- Research article
- Open Access
The red fluorescent protein eqFP611: application in subcellular localization studies in higher plants
© Forner and Binder; licensee BioMed Central Ltd. 2007
- Received: 08 November 2006
- Accepted: 06 June 2007
- Published: 06 June 2007
Intrinsically fluorescent proteins have revolutionized studies in molecular cell biology. The parallel application of these proteins in dual- or multilabeling experiments such as subcellular localization studies requires non-overlapping emission spectra for unambiguous detection of each label. In the red spectral range, almost exclusively DsRed and derivatives thereof are used today. To test the suitability of the red fluorescent protein eqFP611 as an alternative in higher plants, the behavior of this protein was analyzed in terms of expression, subcellular targeting and compatibility with GFP in tobacco.
When expressed transiently in tobacco protoplasts, eqFP611 accumulated over night to levels easily detectable by fluorescence microscopy. The native protein was found in the nucleus and in the cytosol and no detrimental effects on cell viability were observed. When fused to N-terminal mitochondrial and peroxisomal targeting sequences, the red fluorescence was located exclusively in the corresponding organelles in transfected protoplasts. Upon co-expression with GFP in the same cells, fluorescence of both eqFP611 and GFP could be easily distinguished, demonstrating the potential of eqFP611 in dual-labeling experiments with GFP. A series of plasmids was constructed for expression of eqFP611 in plants and for simultaneous expression of this fluorescent protein together with GFP. Transgenic tobacco plants constitutively expressing mitochondrially targeted eqFP611 were generated. The red fluorescence was stably transmitted to the following generations, making these plants a convenient source for protoplasts containing an internal marker for mitochondria.
In plants, eqFP611 is a suitable fluorescent reporter protein. The unmodified protein can be expressed to levels easily detectable by epifluorescence microscopy without adverse affect on the viability of plant cells. Its subcellular localization can be manipulated by N-terminal signal sequences. eqFP611 and GFP are fully compatible in dual-labeling experiments.
- Green Fluorescent Protein
- Green Fluorescent Protein Fluorescence
- Tobacco Protoplast
- Green Fluorescent Protein Fusion Protein
- Peroxisomal Target Signal
Since the cloning of the green fluorescent protein (GFP) cDNA and its first heterologous expression in the early 1990s [1, 2], the use of intrinsically fluorescent proteins (IFPs) has become one of the most powerful tools in molecular and cell biology. These proteins are applied as reporters in gene expression studies, as indicators of intra-cellular physiological changes, for monitoring dynamics of organelles and proteins, for investigation of protein-protein interactions in vivo and as fusion partners in studies of the subcellular localization of proteins [3, 4].
From the very beginning, many efforts have been made to optimize various features of the native GFP with the aim to improve its application in biological research. These modifications include for instance improved folding efficiency, higher expression level or increased solubility . Cyan and yellow fluorescent derivatives of GFP have been created for investigations requiring the simultaneous distinguishable tagging of more than one protein at a time [5, 4]. These are used to compare the spatial distribution or the expression pattern of two or more proteins and for the analysis of protein-protein interactions by FRET. So far no red fluorescent variant of GFP has been reported. Recently, investigation of several non-bioluminescent anthozoan species has led to the isolation of various true red fluorescent proteins (RFPs) . Among these, DsRed and its derivatives are the most commonly used in molecular and cell biological research .
Since plants contain a large number of multi-gene families, comparisons of the subcelluar localizations of the individual members are necessary as part of the comprehensive analysis of these proteins. The possibility to label several proteins with different fluorescent proteins is a great advantage when analyzing their respective subcellular localization. As a crucial prerequisite for such studies, the compartments to which the fusion proteins are targeted have to be unequivocally identified. This is often done by staining with compartment-specific dyes. Mitochondria for instance can be visualized by staining with the red fluorescent dye MitoTracker® Red CM-H2Xros (Molecular Probes, Eugene, OR) which specifically interacts with the respiratory chain. The staining procedure, however, is time-consuming, invasive and short-lived and can be replaced simply by co-expression of a spectrally different second fusion protein with a defined subcellular localization. Additionally, the fused target sequence of the fluorescent marker protein can be readily exchanged, which allows selective labeling of nearly every subcellular structure under investigation without the need to have a specific dye for the different compartments.
Despite the discovery of a multiplicity of fluorescent proteins in the red spectral range in recent years , so far almost exclusively different forms of DsRed have been used for studies in molecular cell biology in plants [8–12]. These proteins are applied in dual-labeling experiments together with GFP or alone to report on promoter activity or as a marker in transgenic plants. To introduce an alternative RFP for the application in plant cells and to expand the palette of red fluorescent reporters for plant research, we tested the suitability of the red fluorescent protein eqFP611 from the sea anemone Entacmaea quadricolor as a marker in subcellular localization experiments in plants.
eqFP611 shows far-red fluorescence with excitation and emission maxima at 559 nm and 611 nm, respectively, and therefore exhibits an extraordinarily large Stokes shift of 52 nm . In contrast, the respective values for DsRed are 558 nm, 583 nm and 25 nm, respectively . Both eqFP611 and DsRed have comparable molecular masses of 25.93 kDa and 26.05 kDa, respectively, for the monomers. The extinction coefficient of eqFP611 (78,000 M-1* cm-1) is slightly higher than that of DsRed (75,000 M-1* cm-1). Fluorescence quantum yields for eqFP611 and DsRed are 0.45 and 0.7 and the photobleaching quantum yields are 3.5 * 10-6 and 0.8–9.5 * 10-6, respectively. Similar to DsRed, the emission of eqFP611 is constant between pH 4 and 10. Though both form tetramers at physiological concentrations, eqFP611 has a reduced tendency to oligomerize and aggregate as compared to DsRed. With a maturation half-time t0.5 of 4.5 h at 24.5°C , fluorophore maturation of eqFP611 is much faster than that of DsRed (t0.5 > 24 h at 24.5 °C) .
We demonstrate that native eqFP611 can be expressed in plant cells. Fusions of this protein with respective N-terminal signal sequences can be efficiently targeted to mitochondria and peroxisomes. We performed co-expression experiments with eqFP611 and GFP and created vectors for the straightforward application of the eqFP611 gene in plants.
eqFP611 can be functionally expressed in plant cells
Recently, eqFP611, the gene for a red fluorescent protein from the sea anemone Entacmaea quadricolor, has been cloned and characterized [13, 14]. This protein has been succesfully expressed in bacteria and animal cells , but has not yet been tested in plants.
These results show that eqFP611 can be readily used in plants, since the functional protein accumulates to detectable levels without any obvious adverse effects. In contrast to GFP, whose original jellyfish-derived cDNA was misspliced specifically in plants at a cryptic splice site , no modification of the eqFP611 coding sequence is necessary for efficient expression in plants.
As expected from its spectral characteristics, the fluorescence is easily detectable with a filter set (see above) that excludes the red autofluorescence of chlorophyll, a crucial advantage for an RFP applied in mesophyll cells. Similar to GFP , the native eqFP611 accumulates in the nucleus and in the cytosol in plant cells. Thus, it should be suited to investigate protein targeting into e.g. mitochondria, peroxisomes and plastids within plants. In HeLa cells, native, unmodified eqFP611 was also found in the nucleus and the cytosol .
Targeting eqFP611 to mitochondria
The picture of the transfected protoplast displayed in Fig. 2A demonstrates nicely that the use of the MitoTracker filter set is appropriate to easily detect the red fluorescence of eqFP611 while effectively blocking chlorophyll autofluorescence. The latter is clearly visible through the FITC (fluorescein isothiocyanate) filter set (HQ 470/40/HQ 500 LP), which in turn blocks the fluorescence of eqFP611 (Fig. 2B). This autofluorescence in the chloroplasts exactly fits to the areas without fluorescence in Fig. 2A. Furthermore, the untransfected cells surrounding the eqFP611-expressing protoplast in Fig. 2A clearly show that no other autogenous fluorescence is visible through the MitoTracker filter set.
To assess the relative stability of the eqFP611 fluorescence in plants, we qualitatively compared the time elapsed until bleaching of the red fluorescence in protoplasts transiently expressing IVD145-eqFP611 and of MitoTracker® Red CM-H2Xros (Molecular Probes, Eugene, OR) used for staining of untransfected protoplasts. This latter mitochondria-specific fluorescent dye has excitation/emission maxima of 579 nm and 599 nm, respectively. When individual cells of both approaches were inspected under identical light conditions in the fluorescence microscope, the fluorescence of IVD145-eqFP611 was at least as stable as the fluorescence of MitoTracker, which further demonstrates the usability of eqFP611 as marker at least in plant mitochondria.
Co-expression of eqFP611 and smGFP4 in tobacco protoplasts
Thus, as demonstrated by the expression in both mitochondria and peroxisomes, eqFP611 is a suitable partner for GFP in double-labeling experiments. When the two IFPs are co-expressed in the same cell, no mutual interference regarding development of fluorescence or intracellular sorting is observed. Additionally, both eqFP611 and GFP fluorescences can be easily distinguished by their emission spectra. The previously reported minor green fluorescence of eqFP611 was undetectable under the conditions used (Fig. 2B and 4B) .
Furthermore, despite the tendency of eqFP611 to form tetramers , its fusion proteins can be efficiently and reliably targeted to organelles. The transport across single (peroxisomes) or double (mitochondria) membranes does not interfere with the formation of the higher order structure necessary for emitting fluorescence. In addition, the fusion of a signal sequence to its N-terminus has no negative influence on the red fluorescence of eqFP611.
Expression of both eqFP611 and smGFP4 from a single plasmid
Tobacco plants stably expressing mitochondrially targeted eqFP611
Our results consistently demonstrate that eqFP611 meets all requirements for a potential fluorescent reporter protein for application in plants. It can be expressed in plant cells from the unmodified E. quadricolor cDNA sequence to levels easily detectable by epifluorescence microscopy without any adverse affect on viability. eqFP611 fluorescence can readily be separated from the red chlorophyll autofluorescence by using appropriate filter sets. Its subcellular localization can be efficiently controlled by N-terminal signal sequences. eqFP611 and GFP are fully compatible in dual-labeling experiments since there is no cross-interference with regard to expression and intra-cellular sorting and their fluorescence spectra can be clearly distinguished.
In addition, the plasmids created in the course of this work are convenient tools for the investigation of the subcellular localization of proteins in plant cells. The constructs encoding IFP fusions proteins with mitochondrial and peroxisomal targeting sequences can be used to express markers for the visualization of the corresponding organelles. The targeting sequences can also be easily exchanged to create new IFP fusions with any protein. Furthermore, all IFP expression cassettes can be transferred by HindIII/EcoRI digestion into the plant transformation vector pBI121 and derivatives thereof. Finally, the tobacco line stably expressing eqFP611 targeted to mitochondria is a useful source for protoplasts with an endogenous mitochondrial marker.
In summary, eqFP611 represents a true alternative to other RFPs and can be added into the tool box of red fluorescent proteins for use in plants.
Plasmid construction/cloning strategy
The eqFP611 wild-type coding sequence (696 bp) was PCR amplified from a respective cDNA clone  with primers eqFP611-H 5'-cacccgggatgaactcactgatcaagg-3' (in which the EcoRI site at nucleotide position 4 relative to the start codon was eliminated) and eqFP611-R 5'-tcgagctctcaaagacgtcccagtttg-3'. The PCR product was digested with XmaI and SacI and cloned into the respective site in the vector pIVD145-smGFP4 , in which eqFP611 replaced the smGFP4 gene. The resulting plasmid pIVD145-eqFP611 was used for studying mitochondrial targeting.
The plasmid peqFP611 for the expression of eqFP611 without presequence was obtained by excision of the IVD presequence from pIVD145-eqFP611 by BamHI digestion followed by religation.
To follow targeting into peroxisomes pKAT2-eqFP611 was constructed as follows: Primers KAT2-5'-2 5'-tctagaccatggagaaagcgatcgag-3' and KAT2-3'-2 5'-cccgggagggtcacctacttcacttgg-3' were used to amplify the N-terminal part (297 bp) of the 3-keto-acyl-CoA thiolase 2 (KAT2, At2g33150) coding sequence using total oligo(dT) primed cDNA from A. thaliana seedlings. The PCR product was cloned using the pGEM®-T Vector System I kit (Promega), sequenced, excised with XbaI and SmaI and ligated into plasmid peqFP611. The 99 amino-acid long N-terminal part from KAT2 including the peroxisomal targeting signal 2 (from amino acids 1 to 34) is now fused in frame upstream the eqFP611 coding sequence [21, 22].
To study subcellular targeting of two fusion proteins simultaneously, a plasmid carrying two genes for different fluorescent proteins fused to identical mitochondrial targeting sequences (pIVD144-eqFP611-IVD145-smGFP4) was constructed. Briefly, IVD-eqFP611 and IVD-smGFP4 fusions both under control of a CaMV 35S promoter were introduced into the same plasmid in head-to-head orientation separated by a spacer sequence. Both presequences can be exchanged separately by XhoI (eqFP611) and BamHI (smGFP4) restriction digestion, respectively. Cloning details are available on request.
For constitutive expression of eqFP611 and GFP fusion proteins in plants, plasmids suitable for agrobacteria-mediated transformation were constructed. To generate pIVD145-eqFP611-pBI121, the HindIII-EcoRI fragment containing the eqFP611 expression cassette was removed from plasmid pIVD145-eqFP611 by cutting with EcoRI and partial digestion with HindIII. This DNA fragment was ligated into pBI121 digested with the same enzymes, which replaces the GUS cassette in this vector.
An analogous approach was used to generate pIVD144-eqFP611-IVD145-smGFP4-pBI121 from pIVD144-eqFP611-IVD145-smGFP4 and pBI121, except that the HindIII digestion was complete.
The vector backbone of psmGFP4 (sometimes also designated psmGFP) has been reported to be based on pUC118 and to contain the sequence ggatccaaggagatataacaatgagt around the smGFP4 start codon (bold) [GenBank: U70495] . Our plasmid psmGFP4 and all its derivatives deviate from the published configuration in some aspects. Sequencing of pIVD145-smGFP4 shows the sequence downstream of the CaMV 35S promoter to be tctagaggatcctatg...(IVD)... ggatcccgcccgggatg...(smGFP4)... (start codons in bold). PCRs with one primer binding in the vector backbone and the other one in the CaMV 35S promoter or smGFP4 coding sequence in our psmGFP4 clearly show that the multiple cloning site is not orientated like in pUC118 and pUC18 but like in pUC119 and pUC19 (data not shown).
The absence of a 473 bp fragment in a digestion of the plasmid pIVD144-eqFP611 with RsaI (data not shown) rather indicates a pUC19-like instead of a pUC119-like configuration of the psmGFP4-derived vector-backbone.
Polymerase chain reactions
All PCRs were performed with BD Advantage™ 2 Polymerase Mix (Becton Dickinson GmbH, Heidelberg, Germany), Phusion™ High-Fidelity DNA Polymerase (BioCat GmbH, Heidelberg, Germany) or self-produced Taq polymerase, respectively. Amplifications were done in 22 to 35 cycles under conditions recommended by the manufacturer (BD Advantage 2, Phusion). Reactions with self-produced Taq polymerase were done following standard protocols .
All PCR-derived DNA fragments were sequenced after cloning, except the RFP-expression cassette in pIVD144-eqFP611-IVD145-smGFP4. In this case, only the IVD144 mitochondrial presequence was analyzed by sequencing.
PEG-mediated transient transfection of protoplasts was essentially carried out as described previously . For transfection with single constructs, 60 μg DNA were used. In case of simultaneous transfection with two separate plasmids, 30 μg to 60 μg of each plasmid DNA were used.
Transgenic Nicotiana tabacum L., cv Petit Havana plants were generated essentially as described elsewhere . Expression of IVD145-eqFP611 in the T0, T1, T2 and T3 plants was followed by fluorescence microscopic analysis of parts of the lower epidermis of leaves.
Agrobacteria-mediated transformation of N. benthamiana by leaf infiltration was performed as described before .
Strain GV2260 of A. tumefaciens was used for experiments requiring T-DNA transfer.
A Carl Zeiss Axioplan I microscope and the axiovision software (Carl Zeiss, Oberkochen, Germany) were used for visualization and documentation of eqFP611 and GFP fluorescence. The microscope was equipped with FITC (fluorescein isothiocyanate) (HQ 470/40/HQ 500 LP) and MitoTracker (HQ545/30/HQ 610/75) filter sets obtained from AHF (Tübingen, Germany) for GFP and eqFP611 analysis, respectively.
We thank Jörg Wiedenmann for providing the pQE32-based eqFP611 cDNA clone and critical reading of the manuscript, Jeff Harper for generous gift of plasmid p35S-N-TAP2(G)pex and Edyta Bocian for subcloning of the eqFP611 expression cassette from pIVD145-eqFP611 into pBI121. The authors are also grateful to Bärbel Weber for excellent technical assistance with protoplast preparation and transfection as well as fluorescence microscopy and to Carmen Schilling-Kolle for transformation of pIVD145-eqFP611-pBI121 into tobacco as well as cultivation of the wild-type tobacco plants. This work was supported by the Deutsche Forschungsgemeinschaft, the Rudolf und Clothilde Eberhardt-Stiftung and a fellowship of the Studienstiftung des deutschen Volkes to JF.
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