Generation and Comparison of Bioluminescent and Fluorescent Bacillus licheniformis

The environmental bacterium Bacillus licheniformis was transformed with two different shuttle-vectors (pCSS810 and pGFPratiometric) containing insect luciferase and green fluorescent protein genes, respectively. The cells were treated with various antimicrobial agents and the emitted bioluminescence and fluorescence were measured. Plasmid harboring the green fluorescent protein gene was totally segregated without selective pressure, and fluorescent B. licheniformis showed a slower growth rate than the wild-type strain; those cells were bright green as visualized by epifluorescent microscopy. However, fluorescence was not correlated to the growth state of cells or affected by the antibiotic treatments. To the contrary, luminescent transformant was found to be stable without antibiotic selection and showed analogous growth behavior compared to non-plasmid-bearing cells. The luminescent strain functioned as a biosensor for the antibiotics employed. Bioluminescence measurements allowed one to determine the viability of the recombinant cells and the kinetics of the antibacterial action could be followed. Thus, the light emission was found to be a reliable, sensitive, and real-time indicator of the "well-being" of cells, whereas fluorescence allowed one to visualize both metabolically active and inactive cells.     

Chemistries and colors of bioluminescent reactions: a review

Many different organisms, ranging from bacteria and fungi to fireflies and fish, are endowed with the ability to emit light, but the bioluminescent systems are not evolutionarily conserved: genes coding for the luciferase proteins (Lase) are not homologous, and the luciferins are also different, falling into many unrelated chemical classes. Biochemically, all known Lase are oxygenases that utilize molecular oxygen to oxidize a substrate (a luciferin; literally the ‘light-bearing’ molecule), with formation of a product molecule in an electronically excited state. The color of the light may differ, even though the same luciferin/Lase system underlies the reaction. Filters or differences in Lase structure are responsible in some cases; in others a secondary emitter associated with a second protein is involved. In the coelenterates a green fluorescent protein, whose chromophore is derived from the primary amino-acid sequence, results in a red shift of the emission. In the bacteria accessory proteins causing either blue- or red-shifts have been isolated from different species; the chromophores are noncovalently bound. Although radiationless energy transfer has been implicated in the excitation of such accessory emitters, this may not be so in all cases.     

Fluorescent derivatives of the GFP chromophore give a new insight into the GFP fluorescence process

The photophysical properties of synthetic compounds derived from the imidazolidinone chromophore of the green fluorescent protein were determined. Various electron-withdrawing or electron-donating substituents were introduced to mimic the effect of the chromophore surroundings in the protein. The absorption and emission spectra as well as the fluorescence quantum yields in dioxane and glycerol were shown to be highly dependent on the electronic properties of the substituents. We propose a kinetic scheme that takes into account the temperature-dependent twisting of the excited molecule. If the activation energy is low, the molecule most often undergoes an excited-state intramolecular twisting that leads it to the ground state through an avoided crossing between the S(1) and S(0) energy surfaces. For a high activation energy, the torsional motion within the compounds is limited and the ground-state recovery will occur preferentially by fluorescence emission. The excellent correlation between the fluorescence quantum yields and the calculated activation energies to torsion points to the above-mentioned avoided crossing as the main nonradiative deactivation channel in these compounds. Finally, our results are discussed with regard to the chromophore in green fluorescent protein and some of its mutants.     

Multiple forms of "kiss-and-run" exocytosis revealed by evanescent wave microscopy

Exocytotic release of neuropeptides and hormones is generally believed to involve the complete merger of the secretory vesicle with the plasma membrane. However, recent data have suggested that "kiss-and-run" mechanisms may also play a role. Here, we have examined the dynamics of exocytosis in pancreatic MIN6 beta cells by imaging lumen- (neuropeptide Y/pH-insensitive yellow fluorescent protein; NPY.Venus) or vesicle membrane-targeted fluorescent probes (synaptobrevin-2/enhanced green fluorescent protein; synapto.pHluorin, or phosphatase on the granule of insulinoma-enhanced green fluorescent protein, phogrin.EGFP) by evanescent wave microscopy. Unexpectedly, NPY.Venus release events occurred much less frequently (13%-40% maximal rate) than those of synapto.pHluorin, even though the latter molecule, but not phogrin.EGFP, usually diffused away from the site of fusion. Thus, the majority of exocytosis occurs in these cells by kiss-and-run events that involve either the release of small molecules only, small molecules and selected membrane proteins, or all soluble cargoes ("pure," "mixed," and "full" kiss-and-run, respectively). Changes in the activity of synaptotagmin IV, achieved here by overexpression of the wild-type protein, may allow different stimuli to alter the ratio of these events, and thus the release of selected vesicle cargoes.     

利用FRET技术在活细胞内观察EGF对PKA作用的时空成像

cAMP依赖的蛋白激酶(protein kinase A,PKA)在细胞生长与分化过程中扮演重要角色,特别是在调节Ras信号通路引起的细胞增殖效应中起着重要作用。为了在活细胞内动态观察表皮生长因子(epidermal growth factor,EGF)对PKA的作用,采用一种可以检测PKA酶活性的报告蛋白(A-kinase activity reporter,AKAR)——这种报告蛋白是利用荧光共振能量转移(fluorescence resonance energy transfer,FRET)原理设计的,使其在人类肺癌细胞(ASTC-a-1)中稳定表达。加入EGF刺激因子后,随时间变化的成像分析显示出在活细胞生理条件下被EGF作用的PKA酶活性变化的时空信息。这些资料为EGF作用PKA提供了直接的实时证据。     

Simultaneous detection of gfp-marked Moraxella sp. G21r and lux-marked Ralstonia eutrophas H850Lr using most-probable-number method

The green fluorescent protein encoded by gfp gene and the luminescent protein encoded by luxAB genes were used as markers to detect p-nitrophenol (PNP)-degrading Moraxella sp. G21r and polychlorinated biphenyl (PCB)-degrading Ralstonia eutrophas H850Lr cells, respectively, in mixed liquid cultures and in soil samples using a most-probable-number (MPN) assay. Population estimates for both gfp-marked G21r and lux-marked H850Lr by using MPN assays were similar to viable colony counts. The MPN assay with microtiter plates permitted the simultaneous detection of fluorescent and luminescent bacteria in soil samples faster than conventional plate counting.     

Structure‐guided design of a reversible fluorogenic reporter of protein‐protein interactions

A reversible green fluorogenic protein‐fragment complementation assay was developed based on the crystal structure of UnaG, a recently discovered fluorescent protein. In living mammalian cells, the nonfluorescent fragments complemented and rapidly became fluorescent upon rapamycin‐induced FKBP and Frb protein interaction, and lost fluorescence when the protein interaction was inhibited. This reversible fluorogenic reporter, named uPPI [UnaG‐based protein‐protein interaction (PPI) reporter], uses bilirubin (BR) as the chromophore and requires no exogenous cofactor. BR is an endogenous molecule in mammalian cells and is not fluorescent by itself. uPPI may have many potential applications in visualizing spatiotemporal dynamics of PPIs.     

Three photoconvertible forms of green fluorescent protein identified by spectral hole-burning.

Several studies have led to the conclusion that, in the green fluorescent protein (GFP) of the jellyfish Aequorea victoria, a photoconversion involving excited-state proton transfer occurs from an A- to a B-form, while an intermediate I-form was held responsible for the green fluorescence. Here we have identified the I-form of wild-type GFP in absorption, located the 0-0 transitions of all three forms A, B and I, and determined vibrational frequencies of the ground and excited states. The intrinsically narrow 0-0 transitions are revealed by the wavelengths at which holes can be burnt. The pathways of photointerconversion are unraveled by excitation, emission and hole-burning spectroscopy. We present an energy-level scheme that has significant implications for GFP-mutants, which likewise can occur in the three photo-interconvertible forms.     

Combining protein complementation assays with resonance energy transfer to detect multipartner protein complexes in living cells

A variety of fluorescent proteins with different spectral properties have been created by mutating green fluorescent protein. When these proteins are split in two, neither fragment is fluorescent per se, nor can a fluorescent protein be reconstituted by co-expressing the complementary N- and C-terminal fragments. However, when these fragments are genetically fused to proteins that associate with each other in cellulo, the N- and C-terminal fragments of the fluorescent protein are brought together and can reconstitute a fluorescent protein. A similar protein complementation assay (PCA) can be performed with two complementary fragments of various luciferase isoforms. This makes these assays useful tools for detecting the association of two proteins in living cells. Bioluminescence resonance energy transfer (BRET) or fluorescence resonance energy transfer (FRET) occurs when energy from, respectively, a luminescent or fluorescent donor protein is non-radiatively transferred to a fluorescent acceptor protein. This transfer of energy can only occur if the proteins are within 100 Å of each other. Thus, BRET and FRET are also useful tools for detecting the association of two proteins in living cells. By combining different protein fragment complementation assays (PCA) with BRET or FRET it is possible to demonstrate that three or more proteins are simultaneous parts of the same protein complex in living cells. As an example of the utility of this approach, we show that as many as four different proteins are simultaneously associated as part of a G protein-coupled receptor signalling complex.     

Quantitative fluorescence correlation spectroscopy reveals a 1000-fold increase in lifetime of protein functionality

We have investigated dilute protein solutions with fluorescence correlation spectroscopy (FCS) and have observed that a rapid loss of proteins occurs from solution. It is commonly assumed that such a loss is the result of protein adsorption to interfaces. A protocol was developed in which this mode of protein loss can be prevented. However, FCS on fluorescent protein (enhanced green fluorescent protein, mCherry, and mStrawberry) solutions enclosed by adsorption-protected interfaces still reveals a decrease of the fluorescent protein concentration, while the diffusion time is stable over long periods of time. We interpret this decay as a loss of protein functionality, probably caused by denaturation of the fluorescent proteins. We show that the typical lifetime of protein functionality in highly dilute, approximately single molecule per femtoliter solutions can be extended more than 1000-fold (typically from a few hours to >40 days) by adding compounds with surfactant behavior. No direct interactions between the surfactant and the fluorescent proteins were observed from the diffusion time measured by FCS. A critical surfactant concentration of more than 23 μM was required to achieve the desired protein stabilization for Triton X-100. The surfactant does not interfere with DNA-protein binding, because similar observations were made using DNA-cutting restriction enzymes. We associate the occurrence of denaturation of proteins with the activity of water at the water-protein interface, which was recently proposed in terms of the “water attack model”. Our observations suggest that soluble biomolecules can extend an influence over much larger distances than suggested by their actual volume.     

Electronic excitations of biomolecules studied by quantum chemistry

Significant methodological advances have been made over the past ten years in developing reliable quantum chemical methods for the treatment of electronically excited states. These methods can nowadays be used routinely by the experienced researcher to accurately compute excitation spectra of medium-sized organic molecules; results have been reported for several popular photobiological systems, including green fluorescent protein. First steps are currently being taken to account for the solvochromic shifts of chromophore excitations caused by particular protein environments and to dynamically simulate photochemical reactions in the excited states.     

Divergent genetic control of protein solubility and conformational quality in Escherichia coli

In bacteria, protein overproduction results in the formation of inclusion bodies, sized protein aggregates showing amyloid-like properties such as seeding-driven formation, amyloid-tropic dye binding, intermolecular β-sheet architecture and cytotoxicity on mammalian cells. During protein deposition, exposed hydrophobic patches force intermolecular clustering and aggregation but these aggregation determinants coexist with properly folded stretches, exhibiting native-like secondary structure. Several reports indicate that inclusion bodies formed by different enzymes or fluorescent proteins show detectable biological activity. By using an engineered green fluorescent protein as reporter we have examined how the cell quality control distributes such active but misfolded protein species between the soluble and insoluble cell fractions and how aggregation determinants act in cells deficient in quality control functions. Most of the tested genetic deficiencies in different cytosolic chaperones and proteases (affecting DnaK, GroEL, GroES, ClpB, ClpP and Lon at different extents) resulted in much less soluble but unexpectedly more fluorescent polypeptides. The enrichment of aggregates with fluorescent species results from a dramatic inhibition of ClpP and Lon-mediated, DnaK-surveyed green fluorescent protein degradation, and it does not perturb the amyloid-like architecture of inclusion bodies. Therefore, the Escherichia coli quality control system promotes protein solubility instead of conformational quality through an overcommitted proteolysis of aggregation-prone polypeptides, irrespective of their global conformational status and biological properties.     

Quantification of protein interaction in living cells by two-photon spectral imaging with fluorescent protein fluorescence resonance energy transfer pair devoid of acceptor bleed-through

Fluorescence resonance energy transfer (FRET) between fluorescent proteins (FPs) is a powerful method to visualize and quantify protein-protein interaction in living cells. Unfortunately, the emission bleed-through of FPs limits the usage of this complex technique. To circumvent undesirable excitation of the acceptor fluorophore, using two-photon excitation, we searched for FRET pairs that show selective excitation of the donor but not of the acceptor fluorescent molecule. We found this property in the fluorescent cyan fluorescent protein (CFP)/yellow fluorescent protein (YFP) and YFP/mCherry FRET pairs and performed two-photon excited FRET spectral imaging to quantify protein interactions on the later pair that shows better spectral discrimination. Applying non-negative matrix factorization to unmix two-photon excited spectral imaging data, we were able to eliminate the donor bleed-through as well as the autofluorescence. As a result, we achieved FRET quantification by means of a single spectral acquisition, making the FRET approach not only easy and straightforward but also less prone to calculation artifacts. As an application of our approach, the intermolecular interaction of amyloid precursor protein and the adaptor protein Fe65 associated with Alzheimer's disease was quantified. We believe that the FRET approach using two-photon and fluorescent YFP/mCherry pair is a promising method to monitor protein interaction in living cells.     

The Spectral Properties of (-)-Epigallocatechin 3-O-Gallate (EGCG) Fluorescence in Different Solvents: Dependence on Solvent Polarity

(-)-Epigallocatechin 3-O-gallate (EGCG) a molecule found in green tea and known for a plethora of bioactive properties is an inhibitor of heat shock protein 90 (HSP90), a protein of interest as a target for cancer and neuroprotection. Determination of the spectral properties of EGCG fluorescence in environments similar to those of binding sites found in proteins provides an important tool to directly study protein-EGCG interactions. The goal of this study is to examine the spectral properties of EGCG fluorescence in an aqueous buffer (AB) at pH=7.0, acetonitrile (AN) (a polar aprotic solvent), dimethylsulfoxide (DMSO) (a polar aprotic solvent), and ethanol (EtOH) (a polar protic solvent). We demonstrate that EGCG is a highly fluorescent molecule when excited at approximately 275 nm with emission maxima between 350 and 400 nm depending on solvent. Another smaller excitation peak was found when EGCG is excited at approximately 235 nm with maximum emission between 340 and 400 nm. We found that the fluorescence intensity (FI) of EGCG in AB at pH=7.0 is significantly quenched, and that it is about 85 times higher in an aprotic solvent DMSO. The Stokes shifts of EGCG fluorescence were determined by solvent polarity. In addition, while the emission maxima of EGCG fluorescence in AB, DMSO, and EtOH follow the Lippert-Mataga equation, its fluorescence in AN points to non-specific solvent effects on EGCG fluorescence. We conclude that significant solvent-dependent changes in both fluorescence intensity and fluorescence emission shifts can be effectively used to distinguish EGCG in aqueous solutions from EGCG in environments of different polarity, and, thus, can be used to study specific EGCG binding to protein binding sites where the environment is often different from aqueous in terms of polarity.     

Ultrafast Photoconversion of the Green Fluorescent Protein Studied by Accumulative Femtosecond Spectroscopy

The irreversible photoconversion of T203V green fluorescent protein (GFP) via decarboxylation is studied under femtosecond excitation using an accumulative product detection method that allows us to measure small conversion efficiencies of down to ΔOD = 10⁻⁷ absorbance change per pulse. Power studies with 800- and 400-nm pulse excitation reveal that excitation to higher states of the neutral form of the GFP chromophore induces photoconversion very efficiently. The singly excited neutral chromophore is a resonant intermediate of the two-step excitation process that leads to efficient photoconversion. We determine the dynamics of this two-step process by separating the excitation step of the neutral chromophore from the further excitation step to the reactive state in a time-resolved two-color experiment. The dynamics show that a further excitation to the very reactive higher excited state is only possible from the initially excited neutral chromophore and not from the fluorescent intermediate state. For applications of GFP in two-photon fluorescence microscopy, the found photochemical behavior implies that the high intensity conditions used in microscopy can lead to photoconversion easily and care has to be taken to avoid unwanted photoconversion.     

Green fluorescent protein: a perspective

A brief personal perspective is provided for green fluorescent protein (GFP), covering the period 1994-2011. The topics discussed are primarily those in which my research group has made a contribution and include structure and function of the GFP polypeptide, the mechanism of fluorescence emission, excited state protein transfer, the design of ratiometric fluorescent protein biosensors and an overview of the fluorescent proteins derived from coral reef animals. Structure-function relationships in photoswitchable fluorescent proteins and nonfluorescent chromoproteins are also briefly covered.     

Selective chemical labeling of proteins in living cells

Labeling proteins with fluorophores, affinity labels or other chemically or optically active species is immensely useful for studying protein function in living cells or tissue. The use of genetically encoded green fluorescent protein and its variants has been particularly valuable in this regard. In an effort to increase the diversity of available protein labels, various efforts to append small molecules to selected proteins in vivo have been reported. This review discusses recent advances in selective, in vivo protein labeling based on small molecule ligand-receptor interactions, intein-mediated processes, and enzyme-catalyzed protein modifications.     

A green-emitting fluorescent protein from Galaxeidae coral and its monomeric version for use in fluorescent labeling

We have cloned a gene which encodes a fluorescent protein from the stony coral, Galaxeidae. This protein absorbs light maximally at 492 nm and emits green light at 505 nm, and as a result, we have designated it "Azami-Green (AG)." Despite sharing a similar spectral profile with enhanced green fluorescent protein (EGFP) (Clontech), the most popular variant of the Aequorea victoria green fluorescent protein, the identity between these two proteins at the amino acid level is only 5.7%. However, since AG has a high extinction coefficient, fluorescence quantum yield, and acid stability, it produces brighter green fluorescence in cultured cells than EGFP. Similar to other fluorescent proteins isolated from coral animals, AG forms a tight tetrameric complex, resulting in poor labeling of subcellular structures such as the plasma membrane and mitochondria. We have converted tetrameric AG into a monomeric form by the introduction of three amino acid substitutions, which were recently reported to be effective for monomerizing the red fluorescent protein from Discosoma coral (DsRed, Clontech). The resultant monomeric AG allowed for efficient fluorescent labeling of all of the subcellular structures and proteins tested while retaining nearly all of the brightness of the original tetrameric form. Thus, monomeric AG is a useful monomeric green-emitting fluorescent protein comparable to EGFP.     

Ultrasensitive detection of biomolecules with fluorescent dye-doped nanoparticles

Fluorescent-labeled molecules have been used extensively for a wide range of applications in biological detection and diagnosis. A new form of highly luminescent and photostable nanoparticles was generated by doping the fluorescent dye tris(2'2-bipyridyl)dichlororuthenium(II)hexahydrate (Rubpy) inside silica material. Because thousands of fluorescent dye molecules are encapsulated in the silica matrix that also serves to protect Rubpy dye from photodamaging oxidation, the Rubpy-dye-doped nanoparticles are extremely bright and photostable. We have used these nanoparticles successfully in various fluorescence labeling techniques, including fluorescent-linked immunosorbent assay, immunocytochemistry, immunohistochemistry, DNA microarray, and protein microarray. By combining the high-intensity luminescent nanoparticles with the specificity of antibody-mediated recognition, ultrasensitive target detection has been achieved. In all cases, assay results clearly demonstrated the superiority of the nanoparticles over organic fluorescent dye molecules and quantum dots in probe labeling for sensitive target detection. These results demonstrate the potential to apply these newly developed fluorescent nanoparticles in various biodetection systems.     

Mechanical unfolding pathways of the enhanced yellow fluorescent protein revealed by single molecule force spectroscopy

We used single molecule force spectroscopy to characterize the mechanical stability of the enhanced yellow fluorescent protein (EYFP) (a mutant form of the green fluorescent protein (GFP)) and two of its circularly permutated variants. In all three constructs, we found two main unfolding peaks; the first corresponds to a transition state placed close to the termini and the second to a transition state placed halfway through the molecule. We attribute the second transition state to the shear rupture of the beta1- and beta6-strands, which we verified by introducing a point mutation in this region. Although both unfolding peaks were observed in all three EYFP variants, their relative frequency of occurrence varied. Our results demonstrated that the mechanical unfolding pathways in EYFP could be deciphered through the use of circular permutation.