Transient expression of apoaequorin in zebrafish embryos: extending the ability to image calcium transients during later stages of development

When aequorin is microinjected into cleavage-stage zebrafish embryos, it is largely used up by ~24 hours. Thus, it is currently not possible to image Ca(2+) signals from later stages of zebrafish development using this approach. We have, therefore, developed protocols to express apoaequorin, i.e., the protein component of aequorin, transiently in zebrafish embryos and then reconstitute intact aequorin in vivo by loading the coelenterazine co-factor into the embryos separately. Two types of apoaequorin mRNA, aeq-mRNA and aeq::EGFP-mRNA, the latter containing the enhanced green fluorescent protein (EGFP) sequence, were in vitro transcribed and when these were microinjected into embryos, they successfully translated apoaequorin and a fusion protein of apoaequorin and EGFP (apoaequorin-EGFP), respectively. We show that aeq::EGFP -mRNA was more toxic to embryos than equivalent amounts of aeq-mRNA. In addition, in an in vitro reconstitution assay, apoaequorin-EGFP produced less luminescence than apoaequorin, after reconstitution with coelenterazine and with the addition of Ca(2+). Furthermore, when imaging intact coelenterazine-loaded embryos that expressed apoaequorin, Ca(2+ )signals from ~2.5 to 48 hpf were observed, with the spatio-temporal pattern of these signals up to 24 hpf, being comparable to that observed with aequorin. This transient aequorin expression approach using aeq-mRNA provides a valuable tool for monitoring Ca(2+ )signaling during the 2448 hpf period of zebrafish development. Thus, it effectively extends the aequorin-based Ca(2+) imaging window by an additional 24 hours.     

Cloning and expression of the cDNA coding for aequorin, a bioluminescent calcium-binding protein

Aequorin is a bioluminescent protein which consists of a polypeptide chain (apoaequorin), coelenterate luciferin, and bound oxygen. Aequorin produces blue light upon binding Ca2+. We have isolated six recombinant pBR322 plasmids which contain apoaequorin cDNA sequences. A mixed synthetic pBR322 plasmids which contain apoaequorin cDNA sequences. A mixed synthetic oligonucleotide probe was used to identify these cDNAs. An extract of an E. coli strain possessing the largest cDNA contained apoaequorin. This apoaequorin can be converted to aequorin in the presence of coelenterate luciferin, 2-mercaptoethanol, and O2. This cDNA is therefore apparently full-length.     

Overexpression and purification of the recombinant Ca2+-binding protein, apoaequorin

The small, monomeric Ca2+-binding photoprotein, aequorin, emits blue light by an intramolecular reaction when mixed with Ca2+. The photoprotein is made up of coelenterazine and molecular oxygen, bound noncovalently to apoaequorin (apoprotein). The chemical steps leading to light emission, involving the oxidative degradation of coelenterazine, have been studied extensively, but little is known about the active site and how the molecule catalyzes the oxidation of coelenterazine. The three-dimensional structure of the protein has not been determined and therefore answers to these questions have remained unavailable. The present paper describes a procedure for preparing fairly large amounts of apoaequorin and aequorin for X-ray crystallographic studies. It consists of fusing the apoaequorin cDNA to the signal peptide coding sequence of the outer membrane protein A of Escherichia coli, which is under the control of the lipoprotein promoter. When the cDNA was expressed in E. coli, a large excess of the recombinant protein was produced and released into the culture medium. Purification of the protein was accomplished by acid precipitation and DEAE-cellulose chromatography. The procedure yielded 7.4 mg of recombinant apoaequorin with a purity greater than 95% from 200 ml of culture medium. On regeneration with coelenterazine, the recombinant aequorin was fully active with Ca2+.     

Monitoring gene expression in Chinese hamster ovary cells using secreted apoaequorin.

A luminescence method for monitoring gene expression in Chinese hamster ovary cells using apoaequorin as a secreted reporter enzyme is described. In this method, the cell is not disrupted prior to assay as in the earlier aequorin procedure and in the firefly method. The apoaequorin secretion vector is constructed by fusing the DNA fragment of the signal peptide sequence of human follistatin to the apoaequorin gene. Transfection of Chinese hamster ovary cells with the vector causes the apoaequorin to be secreted directly into the culture medium. Assay is carried out by removing a small aliquot of the culture medium, incubating it with coelenterazine, and adding Ca2+ to trigger light emission from the regenerated aequorin. The light intensity is measured with a photomultiplier photometer and is proportional to the amount of apoaequorin present. The method is highly specific and sensitive and can be carried out in a relatively short period of time.     

High-level expression and purification of apoaequorin.

A fairly rapid and improved method for producing large amounts of highly pure apoaequorin, the apoprotein of aequorin which emits light on binding Ca2+, is described. The method consists of fusing the gene of the outer membrane protein A (ompA) secretion signal peptide of Escherichia coli to the apoaequorin gene and expressing the fused gene in the bacterium. The expressed protein is correctly cleaved in the process of being secreted across the cell membrane into the culture medium. The apoaequorin is subsequently purified by acid precipitation and DEAE-cellulose chromatography, yielding a product of greater than 95% purity. The availability of pure apoaequorin makes possible detailed studies of the physical-chemical properties of this Ca2(+)-binding protein and allows for the preparation of pure aequorin for use in highly specific and sensitive assays for Ca2+.     

Apoaequorin monitors degradation of endoplasmic reticulum (ER) proteins initiated by loss of ER Ca(2+)

Apoaequorin was targeted to the cytosol, nucleus, and endoplasmic reticulum of HeLa cells in order to determine the effect of Ca(2+) release from the ER on protein degradation. In resting cells apoaequorin had a rapid half-life (ca. 20-30 min) in the cytosol or nucleus, but was relatively stable for up to 24 h in the ER (t(1/2) > 24 h). However, release of Ca(2+) from the ER, initiated by the addition of inhibitors of the ER Ca(2+)/Mg(2+) ATPase such as 2 microM thapsigargin or 1 microM ionomycin, initiated rapid loss of apoaequorin in the ER, but had no detectable effect on apoaequorin turnover in the cytosol nor the nucleus. This loss of apoprotein was not the result of secretion into the external fluid, and could not be inhibited by inhibitors of protein degradation by proteosomes. Proteolysis of apoaequorin in cell extracts (t(1/2) < 20 min) was completely inhibited in the presence of 1 mM Ca(2+), and this effect was independent of the ER retention signal KDEL at the C-terminus. Proteolysis was unaffected by the presence of selected serine protease inhibitors, or 10 microM Zn(2+), a known caspase-3 inhibitor. The results show that apoaequorin can monitor proteolysis of ER proteins activated by loss of ER Ca(2+). Several Ca(2+)-binding proteins exist in the ER, acting as the Ca(2+) store and chaperones. Our results have important implications both for the role of ER Ca(2+) in cell activation and stress and when using aequorin for monitoring free ER Ca(2+) over long time periods.     

Bacterial expression of in vivo-biotinylated aequorin for direct application to bioluminometric hybridization assays

We have constructed a plasmid suitable for bacterial expression of in vivo-biotinylated photoprotein aequorin. The biotin tag facilitates the isolation of aequorin from crude cell extract and the direct complexation of aequorin with streptavidin for the development of highly sensitive hybridization assays, thereby avoiding the need for chemical crosslinking. The plasmid contains a biotin-acceptor coding sequence fused to an apoaequorin gene. The birA gene, encoding biotin protein ligase (BPL), is inserted downstream of the apoaequorin sequence. BPL biotinylates, posttranslationally, the acceptor domain at a unique position. Functional aequorin is generated by incubating the lysate with coelenterazine and is purified by using a monomeric avidin column that allows elution under nondenaturing conditions. The biotinylated aequorin is complexed with streptavidin and used as a reporter molecule in a hybridization assay. The assay entails immobilization of an oligonucleotide probe on microtiter wells followed by hybridization with a denatured DNA target labeled with biotin through PCR. Streptavidin-biotinylated aequorin is used for quantification of the hybrids. Luminescence is measured in the presence of excess Ca(2+). The analytical range extends from 80 amol of target DNA per well (with a signal-to-background ratio of 2.1) up to 40 fmol per well. The coefficient of variation is about 6%. In vivo-biotinylated aequorin produced from 1 liter of culture is sufficient for 300,000 hybridization assays.     

One-step purification and refolding of recombinant photoprotein aequorin by immobilized metal-ion affinity chromatography

A hexahistidine tag was fused to the N-terminus of apoaequorin. A suitable vector encoding the fusion protein was constructed and used for transformation of Escherichia coli JM109 cells. Apoaequorin was overexpressed under the control of tac promoter. It was found, however, that most of the protein existed in the form of inclusion bodies. Inclusion bodies were solubilized with urea, followed by purification and refolding of (His)(6)-apoaequorin in a single chromatographic step by immobilized metal-ion affinity chromatography using Ni(2+)-nitrilotriacetic acid agarose. The purity, as determined by SDS-PAGE analysis, was greater than 80%. The yield was 0.7-1 mg apoaequorin from a 50 ml bacterial culture. The kinetics of light emission of purified aequorin upon addition of Ca(2+) was typical of the commercial aequorin. The luminescence of the purified aequorin was a linear function of its concentration extending over six orders of magnitude. As low as 0.5 attomoles purified aequorin gave a signal-to-noise ratio of 1.8.     

Effect of calcium chelators on the Ca2+-dependent luminescence of aequorin.

The luminescence of aequorin, a useful tool for studying intracellular Ca2+, was recently found to be inhibited by the free EDTA and EGTA that are present in calcium buffers. In the present study we have examined the effect of the free forms of various chelators in the calibration of [Ca2+] with aequorin. Free EDTA and EGTA in low-ionic-strength solutions strongly inhibited the Ca2+-triggered luminescence of aequorin, causing large errors in the calibration of [Ca2+] (approx. 2 pCa units), whereas in solutions containing 150mM-KCl, errors were relatively small (0.2-0.3 pCa units). Citric acid in low-ionic-strength solutions and [(carbamoylmethyl)imino]diacetic acid in high-ionic-strength solutions showed no inhibition and did not cause detectable error in the calibration of [Ca2+], indicating that they are better chelators than EDTA and EGTA for use with aequorin.     

Bioluminescent immunoassay using a fusion protein of protein A and the photoprotein aequorin

Aequorin is a photoprotein that emits light in the presence of Ca2+ ions. To develop a bioluminescent immunoassay based on the light emission property of aequorin, we have expressed the apoaequorin fusion protein with S. aureus protein A in E. coli by recombinant DNA techniques. The fusion protein expressed was purified by IgG-Sepharose affinity chromatography, gel filtration and HPLC procedures. The purified protein A-apoaequorin fusion protein has both the luminescent activity of aequorin and the IgG-binding ability of protein A. We compared results obtained using the protein A-aequorin fusion protein with those obtained using a protein A conjugated horseradish peroxidase based immunoassay, and found them to yield similar results.     

Sequence comparisons of complementary DNAs encoding aequorin isotypes

Aequorin is the Ca2+-activated photoprotein which participates in the bioluminescence from the circumoral ring of the hydromedusa Aequorea victoria. The nucleotide sequences of five aequorin cDNAs have been compared and shown to code for three aequorin isoforms. The cDNA AEQ1 contains the entire protein coding region of 196 amino acids. The other four cDNAs contain only 70-90% of the coding region and apparently code for at least two other isoforms whose amino acid sequences differ significantly from that encoded by AEQ1. The nucleotide sequences coding for the three isotypes differ at a minimum of 54 positions out of a total of 588 nucleotides necessary to code for apoaequorin. Of these nucleotide differences, 24 account for 23 amino acid replacements, substantiating the microheterogeneity observed during sequencing of purified native aequorin [Charbonneau, H., Walsh, K.A., McCann, R.O., Prendergast, F.G., Cormier, M.J., & Vanaman, T.C. (1985) Biochemistry 24, 6762-6771]. Comparison of the deduced cDNA translations with the native protein sequences suggests the loss of seven residues from the amino terminus during purification of aequorin from Aequorea. Aequorin rapidly extracted from the jellyfish using conditions to minimize proteolysis is shown to have a larger molecular weight than that of purified native aequorin. Escherichia coli expressed aequorin encoded by AEQ1 is shown to have the same molecular weight and isoelectric point as those of one of the isotypes rapidly extracted from Aequorea.     

A C-terminal proline is required for bioluminescence of the Ca(2+)-binding photoprotein, aequorin.

The requirement for a proline residue at the C-terminus of the Ca(2+)-binding photoprotein, aequorin, was investigated by measuring luminescence activities of a series of C-terminal deletion mutants, substitution mutants and an addition mutant. CD spectral measurements of apoaequorin with the C-terminal proline deleted showed a small change in secondary structure. In all cases studied, the C-terminal proline was required for bioluminescence activity.     

Blue fluorescent protein from the calcium-sensitive photoprotein aequorin: catalytic properties for the oxidation of coelenterazine as an oxygenase

Blue fluorescent protein from the calcium-binding photoprotein aequorin (BFP-aq) is a complex of Ca2+ -bound apoaequorin and coelenteramide, and shows luminescence activity like a luciferase, catalyzing the oxidation of coelenterazine with molecular oxygen. To understand the catalytic properties of BFP-aq, various fluorescent proteins (FP-aq) have been prepared from semi-synthetic aequorin and characterized in comparison with BFP-aq. FP-aq has luciferase activity and could be regenerated into native aequorin by incubation with coelenterazine. The results from substrate specificity studies of FP-aq using various coelenterazine analogues have suggested that the oxidation of coelenterazine by BFP-aq in the luciferase reaction and the regeneration process to aequorin might involve the same catalytic site of BFP-aq.     

The in situ regeneration and extraction of recombinant aequorin from Escherichia coli cells and the purification of extracted aequorin.

Recombinant apoaequorin expressed in the periplasmic space of Escherichia coli cells was regenerated into aequorin and extracted from the cells, simultaneously, using a buffer that contained coelenterazine. Due to the mild extraction conditions, the impurities in the extract were minimal. Thus, the purification of extracted aequorin could be accomplished in only two steps, anion-exchange chromatography and hydrophobic interaction chromatography, simply by adsorption and elution in both steps. The purified recombinant aequorin was pure, based on various data, including HPLC analysis and light-emitting activity. The yield of purified aequorin was 25-35 mg from 600 ml of culture, which was over 75% of the total amount of apoaequorin expressed in E. coli cells.     

Reconstitution of blue fluorescent protein from recombinant apoaequorin and synthetic coelenteramide

Blue fluorescent protein of aequorin (BFP) is a complex of Ca²⁺-bound apoaequorin with coelenteramide and is a bifunctional protein, which shows blue fluorescence and the luminescence activity like a luciferase. To reconstitute synthetic BFP (syn-BFP) from apoaequorin and coelenteramide, we established new synthetic route of coelenteramide and prepared highly purified recombinant aequorin using the histidine-tagged secretion system in Escherichia coli cells. As a result, we succeeded in reconstituting syn-BFP quantitatively and the fluorescence and luminescence properties of syn-BFP were identical to that of BFP obtained from aequorin.     

Blue fluorescent protein from the calcium-sensitive photoprotein aequorin is a heat resistant enzyme, catalyzing the oxidation of coelenterazine

Blue fluorescent protein from the calcium-sensitive photoprotein aequorin (BFP-aq) was prepared and determined to be a heat resistant enzyme, catalyzing the luminescent oxidation of coelenterazine (luciferin) with molecular oxygen as a general luciferase. After treatment with excess ethylenediaminetetraacetic acid to remove Ca2+ from BFP-aq, the blue fluorescence shifted to a greenish fluorescence. This greenish fluorescent protein (gFP-aq) was identified as a non-covalent complex of apoaequorin with coelenteramide (oxyluciferin) in a molar ratio of 1:1. By incubation with coelenterazine in the absence of reducing reagents, gFP-aq was converted to aequorin at 25 degrees C. BFP-aq and gFP-aq possessing both fluorescence and luminescence activities may work as novel reporter proteins.     

Imaging calcium dynamics in living plants using semi-synthetic recombinant aequorins

The genetic transformation of the higher plant Nicotiana plumbaginifolia to express the protein apoaequorin has recently been used as a method to measure cytosolic free calcium ([Ca2+]i) changes within intact living plants (Knight, M. R., A. K. Campbell, S. M. Smith, and A. J. Trewavas. 1991. Nature (Lond.). 352:524-526; Knight, M. R., S. M. Smith, and A. J. Trewavas. 1992. Proc. Natl. Acad. Sci. USA. 89:4967-4971). After treatment with the luminophore coelenterazine the calcium-activated photoprotein aequorin is formed within the cytosol of the cells of the transformed plants. Aequorin emits blue light in a dose-dependent manner upon binding free calcium (Ca2+). Thus the quantification of light emission from coelenterazine-treated transgenic plant cells provides a direct measurement of [Ca2+]i. In this paper, by using a highly sensitive photon-counting camera connected to a light microscope, we have for the first time imaged changes in [Ca2+]i in response to cold-shock, touch and wounding in different tissues of transgenic Nicotiana plants. Using this approach we have been able to observe tissue-specific [Ca2+]i responses. We also demonstrate how this method can be tailored by the use of different coelenterazine analogues which endow the resultant aequorin (termed semi-synthetic recombinant aeqorin) with different properties. By using h-coelenterazine, which renders the recombinant aequorin reporter more sensitive to Ca2+, we have been able to image relatively small changes in [Ca2+]i in response to touch and wounding: changes not detectable when standard coelenterazine is used. Reconstitution of recombinant aequorin with another coelenterazine analogue (e-coelenterazine) produces a semi-synthetic recombinant aequorin with a bimodal spectrum of luminescence emission. The ratio of luminescence at two wavelengths (421 and 477 nm) provides a simpler method for quantification of [Ca2+]i in vivo than was previously available. This approach has the benefit that no information is needed on the amount of expression, reconstitution or consumption of aequorin which is normally required for calibration with aequorin.     

Hypoosmotic Shock Induces Increases in Cytosolic Ca2+ in Tobacco Suspension-Culture Cells

Hypoosmotic shock treatment increased cytosolic Ca2+ ion concentration ([Ca2+]cyt) in tobacco (Nicotiana tabacum) suspension-culture cells. [Ca2+]cyt measurements were made by genetically transforming these cells to express apoaequorin and by reconstituting the Ca2+-dependent photoprotein, aequorin, in the cytosol by incubation with chemically synthesized coelenterazine. Measurement of Ca2+-dependent luminescence output thus allowed the direct monitoring of [Ca2+]cyt changes. When cells were added to a hypoosmotic medium, a biphasic increase in [Ca2+]cyt was observed; an immediate small elevation (phase 1) was observed first, followed by a rapid, large elevation (phase 2). Phase 1 [Ca2+]cyt was stimulated by the V-type ATPase inhibitor bafilomycin A1. Phase 2 was inhibited by the protein kinase inhibitor K-252a and required the continued presence of the hypoosmotic stimulus to maintain it. Although Ca2+ in the medium was needed to produce phase 2, it was not needed to render the cells competent to the hypoosmotic stimulus. If cells were subject to hypoosmotic shock in Ca2+- depleted medium, increases in luminescence could be induced up to 20 min after the shock by adding Ca2+ to the medium. These data suggest that hypoosmotic shock-induced [Ca2+]cyt elevation results from the activity of a Ca2+ channel in the plasma membrane or associated hypoosmotic sensing components that require Ca2+- independent phosphorylation and a continued stimulus to maintain full activity.     

Oxidative Signals in Tobacco Increase Cytosolic Calcium

Tobacco (Nicotiana plumbaginifolia) seedlings genetically transformed to express apoaequorin were incubated in h-coelenterazine to reconstitute the calcium-sensitive luminescent protein aequorin. Treatment of these seedlings with hydrogen peroxide resulted in a transient burst of calcium-dependent luminescence lasting several minutes. Even though the hydrogen peroxide stimulus was persistent, the change in cytosolic free calcium concentration ([Ca2+]cyt) was transient, suggesting the presence of a refractory period. When seedlings were pretreated with hydrogen peroxide, there was no increase in [Ca2+]cyt upon a second application, which confirmed the refractory character of the response. Only when the two treatments were separated by 4 to 8 hr was full responsiveness recovered. However, treatment with hydrogen peroxide did not inhibit mobilization of [Ca2+]cyt induced by either cold shock or touching, suggesting that these three signals mobilize different pools of intracellular calcium. To examine whether [Ca2+]cyt is regulated by the redox state of the cytoplasm, we pretreated seedlings with buthionine sulfoximine (to modify cellular glutathione levels) and inhibitors of ascorbate peroxidase. These inhibitors modify the hydrogen peroxide-induced transients in [Ca2+]cyt, which is consistent with their effects on the cellular prooxidant/antioxidant ratio. Treatment with hydrogen peroxide that elicited [Ca2+]cyt increases also brought about a reduction in superoxide dismutase enzyme activity. This reduction could be reversed by treatment with the calcium channel blocker lanthanum. This indicates that there is a role for calcium in plant responses to oxidative stress.