A fluorescent indicator for detecting protein-protein interactions in vivo based on protein splicing

We describe a new method with general applicability for monitoring any protein-protein interaction in vivo. The principle is based on a protein splicing system, which involves a self-catalyzed excision of protein splicing elements, or inteins, from flanking polypeptide sequences, or exteins, leading to formation of a new protein in which the exteins are linked directly by a peptide bond. As the exteins, split N- and C-terminal halves of enhanced green fluorescent protein (EGFP) were used. When a single peptide consisting of an intein derived from Saccharomyces cerevisiae intervening the split EGFP was expressed in Escherichia coli, the two external regions of EGFP were ligated, thereby forming the EGFP corresponding fluorophore. Genetic alteration of the intein, which involved large deletion of the central region encoding 104 amino acids, was performed. In the expression of the residual N- and C-terminal intein fragments each fused to the split EGFP exteins, the splicing in trans did not proceed. However, upon coexpression of calmodulin and its target peptide M13, each connected to the N- and C-terminal inteins, fluorescence of EGFP was observed. These results demonstrate that interaction of calmodulin and M13 triggers the refolding of intein, which induces the protein splicing, thereby folding the ligated extein correctly for yielding the EGFP fluorophore. This method opens a new way not only to screen protein-protein interactions but also to visualize the interaction in vivo in transgenic animals.     

Probes for detection of specific DNA sequences at the single-molecule level

A method has been developed for highly sensitive detection of specific DNA sequences in a homogeneous assay using labeled oligonucleotide molecules in combination with single-molecule photon burst counting and identification. The fluorescently labeled oligonucleotides are called smart probes because they report the presence of complementary target sequences by a strong increase in fluorescence intensity. The smart probes consist of a fluorescent dye attached at the terminus of a hairpin oligonucleotide. The presented technique takes advantage of the fact that the used oxazine dye JA242 is efficiently quenched by complementary guanosine residues. Upon specific hybridization to the target DNA, the smart probe undergoes a conformational change that forces the fluorescent dye and the guanosine residues apart, thereby increasing the fluorescence intensity about six fold in ensemble measurements. To increase the detection sensitivity below the nanomolar range, a confocal fluorescence microscope was used to observe the fluorescence bursts from individual smart probes in the presence and absence of target DNA as they passed through the focused laser beam. Smart probes were excited by a pulsed diode laser emitting at 635 nm with a repetition rate of 64 MHz. Each fluorescence burst was identified by three independent parameters: (a) the burst size, (b) the burst duration, and (c) the fluorescence lifetime. Through the use of this multiparameter analysis, higher discrimination accuracies between smart probes and hybridized probe-target duplexes were achieved. The presented multiparameter detection technique permits the identification of picomolar target DNA concentrations in a homogeneous assay, i.e., the detection of specific DNA sequences in a 200-fold excess of labeled probe molecules.     

Real-time monitoring of intracellular mRNA hybridization inside single living cells

A molecular beacon, an oligonucleotide probe with inherent signal transduction mechanisms, is an optimal tool for visualizing real-time mRNA hybridization in single living cells. Each molecular beacon (MB) consists of a single-stranded DNA molecule in a stem-loop conformation with a fluorophore linked to the 5' end and a quencher at the 3' end. In this study, we demonstrate real-time monitoring of mRNA-DNA hybridization inside living cells using molecular beacons. A MB specific for beta-actin mRNA has been designed and synthesized. After microinjection into the cytoplasm of single living kangaroo rat kidney cells (PtK2 cells), the MB hybridizes with beta-actin mRNA as shown by fluorescence measurements over time. Hybridization dynamics have been followed. Strict control experiments have been carried out to confirm that the fluorescence signal increase is indeed due to the hybridization of mRNA inside single living cells. Variation in the MB/mRNA hybridization fluorescent signal has been observed for different PtK2 cells, which indicates the amount of mRNA in different cells is different. We have also monitored the beta-1 andrenergic receptor mRNA inside the PtK2 cells. These studies demonstrate the feasibility of using MBs and the ultrasensitivity achieved in our fluorescence imaging system for real-time detection of mRNA hybridization and for the visualization of oligonucleotide/mRNA interactions inside single living cells.     

Detection of peroxidase/H2O2-mediated oxidation with enhanced yellow fluorescent protein

The ability to sense oxidative stress in live cells and organisms would have far-reaching implications for biotechnology, drug discovery, and potentially medical imaging. We hypothesized that tyrosine-containing fluorescent proteins could be used as switches for sensing oxidative stress, based on their sensitivity to environmental and structural variations. We therefore tested purified EGFP, EYFP, ECFP, and DsRed proteins against the heme-peroxidase/H(2)O(2) reaction. We found that peroxidase-mediated oxidation resulted in up to 99.5% quenching of EYFP fluorescence (but not that of other fluorescent proteins) in a dose-dependent manner. Western blotting revealed inter- and intramolecular cross-linking. The observed detection limit for hydrogen peroxide was approximately 100 nM, well below the extracellular levels previously reported to occur in mammalian tissue during signaling. Combined expression of EYFP (quenchable) and ECFP or EGFP (nonquenchable) is expected to allow sensitive monitoring of oxidative stress.     

A genetically encoded fluorescent indicator capable of discriminating estrogen agonists from antagonists in living cells

A genetically encoded fluorescent indicator was developed for the detection and characterization of estrogen agonists and antagonists. Two different color mutants of green fluorescent protein were joined by a tandem fusion domain composed of LXXLL (L = leucine, X = any amino acid) motif from the nuclear receptor-box II of steroid receptor coactivator 1, a flexible linker sequence, and the estrogen receptor alpha ligand binding domain (ERalpha LBD). Monitoring real-time ligand-induced conformational change in the ERalpha LBD to recruit the LXXLL motif allowed screening of natural and synthetic estrogens in single living cells using fluorescence resonance energy-transfer technique. The indicator was named SCCoR (single cell-coactivator recruitment). The high sensitivity of the present indicator made it possible to distinguish between estrogen strong and weak agonists in a dose-dependent fashion, immediately after adding ligand to live cells. Discrimination of agonists from antagonists was efficiently achieved using the present study. The approach described here can be applied to develop biosensors for other hormone receptors as well.     

Multicolor polystyrene nanospheres tagged with up-conversion fluorescent nanocrystals

Compared to conventional down-conversion fluorescent materials, NIR-to-visible up-conversion fluorescent materials which emit visible light upon near-infrared (NIR) excitation are better suited for biodetection/bioimaging due to their advantages such as minimum photo-damage to living organisms, weak background fluorescence, low signal-to-noise ratio and high detection sensitivity. Uniform hexagonal NaYF(4) (β-NaYF(4)) nanocrystals with up-conversion fluorescence were synthesized. Monodisperse polystyrene nanospheres with an average size of 400?nm in diameter, tagged with different color β-NaYF(4) nanocrystals, were prepared using a miniemulsion polymerization method. More than 20 β-NaYF(4) nanocrystals were encapsulated in a single polystyrene nanosphere. The nanospheres emit multicolor NIR-to-visible up-conversion fluorescence upon excitation at a wavelength of 980?nm. The nanospheres could be used for a variety of biological applications which require high-sensitivity detection of biomolecules.     

Probing single molecules in single living cells

Single-molecule detection in single living cells has been achieved by using confocal fluorescence microscopy and externally tagged probe molecules. The intracellular background fluorescence is substantially higher than that in aqueous buffer, but this background is continuous and stable and does not significantly interfere with the measurement of single-molecule photon bursts. As a result, single-molecule data have been obtained on three types of fluorescent probes at spatially resolved locations (e.g., cytoplasm and nucleus) inside human HeLa cells. First, the iron transport protein transferrin labeled with tetramethylrhodamine undergoes rapid receptor-mediated endocytosis, and single transferrin molecules are detected inside living cells. Second, the cationic dye rhodamine 6G (R6G) enters cultured cells by a potential-driven process, and single R6G molecules are observed as intense photon bursts when they move in and out of the intracellular laser beam. Third, we report results on synthetic oligonucleotides that are tagged with a fluorescent dye and are taken up by living cells via a passive, nonendocytic pathway.     

Nonbleaching fluorescence of gold nanoparticles and its applications in cancer cell imaging

In this paper, we investigated the fluorescent properties of gold nanoparticles (GNPs) with several tens of nanometers by ensemble fluorescence spectrometry, fluorescence correlation spectroscopy (FCS), and fluorescence microscopy. We observed that GNPs synthesized by the citrate reduction of chloroauric acid possessed certain fluorescence, narrow full width at half-maximum (17 nm), and with an increase of particle sizes, the emission intensity showed a gradual increase while the emission wavelength remained almost constant (at 610 nm). Especially, the fluorescence of GNPs possessed the excellent behavior of antiphotobleaching under strong light illumination. Despite their low quantum yields, GNPs exhibited strong native fluorescence under relatively high excitation power. The fluorescence of GNPs could be characterized by fluorescence imaging and FCS at the single particle level. On the basis of this excellent antiphotobleaching of GNPs and easy photobleaching of cellular autofluorescence, we developed a new method for imaging of cells using GNPs as fluorescent probes. The principle of this method is that after cells stained with GNPs or GNPs bioconjugates are illuminated by strong light, the cellular autofluorescence are photobleached and the fluorescence of GNPs on cell membrane or inside cells can be collected for cell imaging. On the basis of this principle, we imaged living HeLa cells using GNPs as fluorescent probes and obtained good cell images by photobleaching of cellular autofluorescence. Furthermore, anti-EGFR/GNPs were successfully used as targeted probes for fluorescence imaging of cancer cells. Our preliminary results demonstrated that GNPs possessed excellent behaviors of antiphotobleaching and were good fluorescent probes in cell imaging. Our cellular imaging method described has potential applications in cancer diagnostics, studies, and immunoassays.     

Counting single native biomolecules and intact viruses with color-coded nanoparticles

Nanometer-sized particles such as semiconductor quantum dots and energy-transfer nanoparticles have novel optical properties such as tunable light emission, signal brightness, and multicolor excitation that are not available from traditional organic dyes and fluorescent proteins. Here we report the use of color-coded nanoparticles and dual-color fluorescence coincidence for real-time detection of single native biomolecules and viruses in a microfluidic channel. Using green and red nanoparticles to simultaneously recognize two binding sites on a single target, we demonstrate that individual molecules of genes, proteins, and intact viruses can be detected and identified in complex mixtures without target amplification or probe/target separation. Real-time coincidence analysis of single-photon events allows rapid detection of bound targets and efficient discrimination of excess unbound probes. Quantitative studies indicate that the counting results are remarkably precise when the total numbers of counted molecules are more than 10. The use of bioconjugated nanoparticle probes for single-molecule detection is expected to have important applications in ultrasensitive molecular diagnostics, bioterrorism agent detection, and real-time imaging and tracking of single-molecule processes inside living cells.     

Quantum measurement and orientation tracking of fluorescent nanodiamonds inside living cells

Fluorescent particles are routinely used to probe biological processes. The quantum properties of single spins within fluorescent particles have been explored in the field of nanoscale magnetometry, but not yet in biological environments. Here, we demonstrate optically detected magnetic resonance of individual fluorescent nanodiamond nitrogen-vacancy centres inside living human HeLa cells, and measure their location, orientation, spin levels and spin coherence times with nanoscale precision. Quantum coherence was measured through Rabi and spin-echo sequences over long (>10 h) periods, and orientation was tracked with effective 1° angular precision over acquisition times of 89 ms. The quantum spin levels served as fingerprints, allowing individual centres with identical fluorescence to be identified and tracked simultaneously. Furthermore, monitoring decoherence rates in response to changes in the local environment may provide new information about intracellular processes. The experiments reported here demonstrate the viability of controlled single spin probes for nanomagnetometry in biological systems, opening up a host of new possibilities for quantum-based imaging in the life sciences.     

IL-2 or IL-4 mRNA as a potential flow cytometric marker molecule for selective collection of living T helper 1 or T helper 2 lymphocytes

Flow cytometry has been widely used to analyze and sort out particular types of living cells that have specific marker molecules. In many cases, marker proteins are present on the cell surface and are detected by monoclonal antibodies against them. However, there are some cases in which cells do not have specific marker molecules on their surface. In this situation, it would be useful if mRNA that is expressed specifically in the particular cell could be used as a marker molecule. We previously reported that mRNA can be detected in living cells by hybridizing a pair of fluoreophore (donor or acceptor)-labeled oligonucleotides to adjacent locations on the target mRNA in the cytoplasm of cells (Tsuji, A.; Koshimoto, H.; Sato, Y.; Hirano, M.; Sei-Iida, Y.; Kondo, S.; Ishibashi, K. Biophys. J. 2000, 78, 3260-3274). On the formed hybrid of the two fluorescent oligonucleotides with the target mRNA, the distance between the two fluorophores becomes very close, which results in fluorescence resonance energy transfer (FRET). Combining this fluorescent labeling method for mRNA with flow cytometry, we have examined the isolation of living CD4+ T helper lymphocytes expressing IL-2 mRNA (Th1) or IL-4 mRNA (Th2). A pair of fluorescent oligonucleotides for hybridizing to IL-2 or IL-4 mRNA were introduced into activated CD4+ T lymphocytes by electroporation. The cells were applied to FACS and analyzed by FRET signals. Th1 or Th2 lymphocytes were exclusively sorted from their mixed populations in activated CD4+ T cells. Our results demonstrate that it is possible to use mRNA as marker molecules to analyze and isolate living cells in flow cytometry.     

Species-specific identification of mycobacterial 16S rRNA PCR amplicons using smart probes

Due to growing problems with new emerging pathogens, cost-effective and manageable methods for their accurate identification in routine diagnostics are urgently required. Of particular importance is the genus Mycobacterium with its more than 100 species. Identification of these species is hampered by their slow growth in the laboratory and by the obligate need for DNA sequence analysis. To provide a fast and reliable diagnostic tool, we developed a novel approach using fluorescently labeled DNA hairpin structures (smart probes) for selective and sensitive detection of mycobacterial 16S rDNA PCR amplicons in homogeneous and heterogeneous assays. Smart probes are singly labeled hairpin-shaped oligonucleotides bearing a fluorescent dye at the 5'-end, which is quenched by guanosine residues in the complementary stem. Upon hybridization to target sequences, a conformational change occurs reflected in an increase in fluorescence intensity. Using optimized parameters for hybridization experiments we established a reliable method for the specific detection of Mycobacterium tuberculosis (M. tuberculosis complex) and Mycobacterium xenopi (member of the atypical mycobacteria) with a detection sensitivity of approximately 2 x 10(-8) M in homogeneous solution. The specificity of the smart probes designed is demonstrated by discrimination of M. tuberculosis and M. xenopi against 15 of the most frequently isolated mycobacterial species in a single assay. In combination with a microsphere-based heterogeneous assay format, the technique opens new avenues for the detection of pathogen-specific DNA sequences with hitherto unsurpassed sensitivity.     

Imaging of conformational changes of proteins with a new environment-sensitive fluorescent probe designed for site-specific labeling of recombinant proteins in live cells

We demonstrate herein a new method for imaging conformational changes of proteins in live cells using a new synthetic environment-sensitive fluorescent probe, 9-amino-6,8-bis(1,3,2-dithioarsolan-2-yl)-5H-benzo[a]phenoxazin-5-one. This fluorescent probe can be attached to recombinant proteins containing four cysteine residues at the i, i + 1, i + 4, and i + 5 positions of an alpha-helix. The specific binding of the fluorescent probe to this 4Cys motif enables fluorescent labeling inside cells by its extracellular administration. The high sensitivity of the fluorophore to its environment enables monitoring of the conformational changes of the proteins in live cells as changes in its fluorescence intensity. The present method was applied to calmodulin (CaM), a Ca2+-binding protein that was well-known to expose hydrophobic domains, depending on the Ca2+ concentration. A recombinant CaM fused at its C-terminal with a helical peptide containing a 4Cys motif was labeled with the fluorescent probe inside live cells. The fluorescence intensity changed reversibly depending on the intracellular Ca2+ concentration, which reflected the conformational change of the recombinant CaM in the live cells.     

Single‐Cell Detection of mRNA Expression Using Nanofountain‐Probe Electroporated Molecular Beacons

New techniques for single‐cell analysis enable new discoveries in gene expression and systems biology. Time‐dependent measurements on individual cells are necessary, yet the common single‐cell analysis techniques used today require lysing the cell, suspending the cell, or long incubation times for transfection, thereby interfering with the ability to track an individual cell over time. Here a method for detecting mRNA expression in live single cells using molecular beacons that are transfected into single cells by means of nanofountain probe electroporation (NFP‐E) is presented. Molecular beacons are oligonucleotides that emit fluorescence upon binding to an mRNA target, rendering them useful for spatial and temporal studies of live cells. The NFP‐E is used to transfect a DNA‐based beacon that detects glyceraldehyde 3‐phosphate dehydrogenase and an RNA‐based beacon that detects a sequence cloned in the green fluorescence protein mRNA. It is shown that imaging analysis of transfection and mRNA detection can be performed within seconds after electroporation and without disturbing adhered cells. In addition, it is shown that time‐dependent detection of mRNA expression is feasible by transfecting the same single cell at different time points. This technique will be particularly useful for studies of cell differentiation, where several measurements of mRNA expression are required over time.     

Nuclear localization of aminoacyl-tRNA synthetases using single-cell capillary electrophoresis laser-induced fluorescence analysis

Aminoacyl-tRNA synthetases (aaRSs) are a family of enzymes whose function in specific aminoacylation of tRNAs is central to the process of protein translation, which occurs in the cytoplasm of all living cells. In addition to their well-established cytoplasmic localization, fluorescence microscopy studies and analysis of the aminoacylation state of nuclear tRNAs have revealed that synthetases are localized in the nuclei of cells from several species including Xenopus laevis and Saccharomyces cerevisiae. Whether nuclear localization of aaRSs is a general phenomenon that occurs in all eukaryotic cells is an open question. In the work described here, human methionyl-tRNA synthetase (MRS) and human lysyl-tRNA synthetase (KRS) were expressed in human-derived DeltaH2-1 osteosarcoma cells as enhanced green fluorescent protein (EGFP) fusion proteins. The subcellular localization of these EGFP-aaRSs was first probed by fluorescence microscopy using cells that coexpressed EGFP-aaRS and a nuclear marker fusion protein, nuDsRed. As expected, both aaRSs were present in the cytosol, while only EGFP-MRS was also clearly localized in the nucleus. To confirm these findings, and to investigate a potentially more sensitive, general method for nuclear localization studies, capillary electrophoresis with laser-induced fluorescence (CE-LIF) detection was used to analyze single DeltaH2-1 cells expressing both EGFP-aaRS and nuDsRed. While cytosolic EGFP signals were detected for both EGFP-MRS and EGFP-KRS, only EGFP-MRS was found in the nucleus, along with nuDsRed. The detection of EGFP-MRS in nuclei of DeltaH2-1 cells demonstrates the feasibility of using CE-LIF analysis in nuclear localization studies of proteins in mammalian cells.     

In situ Visualization of Gene Expression Using Polymer‐Coated Quantum–Dot–DNA Conjugates

Imaging of specific mRNA targets in cells is of great importance in understanding gene expression and cell signaling processes. Subcellular localization of mRNA is known as a universal mechanism for cells to sequester specific mRNA for high production of required proteins. Various gene expressions in Drosophila cells are studied using quantum dots (QDs) and the fluorescence in situ hybridization (FISH) method. The excellent photostability and highly luminescent properties of QDs compared to conventional fluorophores allows reproducible obtainment of quantifiable mRNA gene expression imaging. Amine‐modified oligonucleotide probes are designed and covalently attached to the carboxyl‐terminated polymer‐coated QDs via EDC chemistry. The resulting QD–DNA conjugates show sequence‐specific hybridization with target mRNAs. Quantitative analysis of FISH on the Diptericin gene after lipopolysaccharide (LPS) treatment shows that the intensity and number of FISH signals per cell depends on the concentration of LPS and correlates well with quantitative real‐time PCR results. In addition, our QD–DNA probes exhibit excellent sensitivity to detect the low‐expressing Dorsal‐related immunity factor gene. Importantly, multiplex FISH of Ribosomal protein 49 and Actin 5C using green and red QD–DNA conjugates allows the observation of cellular distribution of the two independent genes simultaneously. These results demonstrate that highly fluorescent and stable QD–DNA probes can be a powerful tool for direct localization and quantification of gene expression in situ.     

Protein splicing-based reconstitution of split green fluorescent protein for monitoring protein-protein interactions in bacteria: improved sensitivity and reduced screening time.

In this research, an improved detection system is described that allows an easy in vivo screening and selection of functional interactions between two interacting proteins in bacteria. We earlier reported a new concept for detecting protein-protein interactions based on reconstitution of split-enhanced green fluorescent protein (EGFP) by protein splicing (Ozawa, T.; et al. Anal. Chem. 2000, 72, 5151-5157.): Two putative interacting proteins are genetically fused to the split VDE inteins, which are linked directly to the N- and C-terminal halves of the split EGFP. Association of the interacting proteins results in functional complementation of VDE and protein-splicing reaction that leads to formation of an EGFP fluorophore. This technique simplified detection of protein interactions, but because of the low splicing efficiency of VDE intein, its sensitivity and screening time were not enough for detecting the protein interactions directly in living cells. In this paper, we have explored the use of the DnaE split intein from Synechocystis sp. PCC6803 for intracellular reconstitution of the split EGFP. We examined efficiency of the fluorophore formation by preparing four different split-EGFP types, among which EGFP dissected at the position between 157 and 158 was found to show the strongest fluorescence intensity upon protein interactions. A time required for the formation of EGFP after protein interactions was only 4 h, as compared to 3 days with the VDE intein. The protein interactions were thereby detected by an in vivo selection and screening assay in Escherichia coli on Luria broth agar plates. This improvement permits versatile designs of screening procedures either for ligands that bind to particular proteins or for molecules or mutations that block particular interactions between two proteins of interest.     

Assessing the sensitivity of commercially available fluorophores to the intracellular environment

The use of fluorescence has become commonplace in the biological sciences, with many studies utilizing probes based on commercially available fluorophores to provide insight into cell function and behavior. As these imaging applications become more advanced, it becomes increasingly important to acquire accurate quantitative measurements of the fluorescence signal. Absolute quantification of fluorescence, however, requires the fluorophores themselves to be insensitive to environmental factors such as nonspecific protein interactions and pH. Here, we present a method for characterizing the sensitivity of fluorophores to the cytosolic environment by comparing their fluorescent intensity to an environment-insensitive reference signal before and after intracellular delivery. Results indicated that although the fluorescent intensity of a few fluorophores, e.g., fluorescein, were highly susceptible to the intracellular environment, other fluorophores, e.g., Dylight 649, Alexa647, and Alexa750, were insensitive to the intracellular environment. It was also observed that the sensitivity of the fluorophore could be dependent on the biomolecule to which it was attached. In addition to assessing the environmental sensitivity of fluorophores, a method for quantifying the amount of fluorophores within living cells is also introduced. Overall, the present study provides a means to select fluorophores for studies that require an absolute quantification of fluorescence in the intracellular environment.     

Polymeric sequence probe for single DNA detection

A polynucleotide probe, polymeric sequence probe (PSP), was developed for single molecular detections. PSP is a single-stranded DNA molecule with ~2000 tandem repeat target-binding sequences and label-binding sequences. A single PSP can bind to multiple fluorescent complementary oligos to generate a strong fluorescence signal. Single target molecules bound to PSPs can be clearly visualized by a conventional fluorescence microscope. An ultrasensitive PSP-based assay for Mycobacterium tuberculosis was demonstrated.