Application of Fluorescent Protein Expressing Strains to Evaluation of Anti-Tuberculosis Therapeutic Efficacy In Vitro and In Vivo

The slow growth of Mycobacterium tuberculosis (Mtb), the causative agent of tuberculosis (TB), hinders development of new diagnostics, therapeutics and vaccines. Using non-invasive real-time imaging technologies to monitor the disease process in live animals would facilitate TB research in all areas. We developed fluorescent protein (FP) expressing Mycobacterium bovis BCG strains for in vivo imaging, which can be used to track bacterial location, and to quantify bacterial load in live animals. We selected an optimal FP for in vivo imaging, by first cloning six FPs: tdTomato, mCherry, mPlum, mKate, Katushka and mKeima, into mycobacteria under either a mycobacterial Hsp60 or L5 promoter, and compared their fluorescent signals in vitro and in vivo. Fluorescence from each FP-expressing strain was measured with a multimode reader using the optimal excitation and emission wavelengths for the FP. After normalizing bacterial numbers with optical density, the strain expressing L5-tdTomato displayed the highest fluorescence. We used the tdTomato-labeled M. bovis BCG to obtain real-time images of pulmonary infections in living mice and rapidly determined the number of bacteria present. Further comparison between L5-tdTomato and Hsp60-tdTomato revealed that L5-tdTomato carried four-fold more tdTomato gene copies than Hsp60-tdTomato, which eventually led to higher protein expression of tdTomato. Evaluating anti-TB efficacy of rifampicin and isoniazid therapy in vitro and in vivo using the L5-tdTomato strain demonstrated that this strain can be used to identify anti-TB therapeutic efficacy as quickly as 24 h post-treatment. These M. bovis BCG reporter strains represent a valuable new tool for evaluation of therapeutics, vaccines and virulence.     

In vivo imaging of tumor growth after electrochemotherapy with cisplatin

Imaging methods can give both temporal and spatial dimensions to characterize the processes in progression of and/or treatment of specific disease Subcutaneous tumors can be cured after electrochemotherapy (ECT). Growth and reduction of tumors as a result of cytotoxic therapy can be followed by fluorescence video imaging directly on the same animal after treatment. Imaging of tumors should bring more information on the cellular effects of ECT. Green fluorescent protein (eGFP) expressing B16F10 and LPB tumors implanted in C57Bl/6 mice were treated with ECT with cisplatin. The growth or regression of the tumors was monitored either classically by using a caliper or by a manual definition of the region of interest where critical fluorescence levels were detected on the animals. A very good correlation between the two methods was observed. The eGFP mean fluorescence emission was only slightly affected by ECT with intravenously injected cisplatin. Ex vivo observations under a fluorescence microscope showed that eGFP was only detected on the outer layer of the tumor. No fluorescence was detected in the central part of the tumors, which were necrotic.     

Protein display on the Yarrowia lipolytica yeast cell surface using the cell wall protein YlPir1

A cell surface display system has been developed in the yeast Yarrowia lipolytica using the cell wall protein YlPir1. The red fluorescent protein TurboFP635 was used as a model protein. The expression plasmid in which the YlPIR1 gene without stop-codon was fused in-frame with the nucleotide sequence encoding TurboFP635 was constructed. The thus obtained recombinant protein complex consists of the YlPir1 the C-terminus of which is fused to the N-terminus of red fluorescent protein. Cell surface display of TurboFP635 was confirmed by fluorescent microscopy. This N-terminal system of protein incorporation in the cell wall could be efficiently applied to the cell surface display of enzymes with active sites located near the C-terminus, for example, lipases.     

Design of near-infrared single-domain fluorescent protein GAF-FP based on bacterial phytochrome

Fluorescent proteins (FPs) are widely used as genetically encoded markers for quantitative and noninvasive study of biological processes. Development of biomarkers that are fluorescent in the near-infrared spectral range allows the tissues of animals to be studied at a deeper level because they are more permeable to the light of this wavelength range than that of visible range. Such properties as low molecular weight and monomeric state are important for widespread use of FPs. In this paper, we managed to obtain FP based on the chromophore-binding domain of bacterial phytochrome (BphP) from Rhodopseudomonas palustris (RpB-phP1), named GAF-FP, with a molecular weight of ~19 kDa, which is half that of other FP based on BphP and 1.4 times lower than that of commonly used GFP-like proteins, which are fluorescent in the near-infrared range. In contrast to most other near-infrared FPs, GAF-FP is a monomer, which has a high photostability, and its structure is stable to the incorporation of small peptide inserts. Moreover, GAF-FP is capable of covalent attachment of two different tetrapyrrole chromophores: phycocyanobilin (PCB) and biliverdin (BV), which is contained in mammalian tissues. GAF-FP with attached BV as a chromophore (GAF-FP–BV) has the main absorption band with a maximum at 635 nm. The fluorescence maximum falls at 670 nm, whereby GAF-FP has a high ratio of the fluorescence signal to the background signal even if FP is localized at a depth of several mm below the tissue surface. Together with the near-infrared absorption band, GAF-FP–BV also has an absorption band in the violet region of the spectrum with a maximum at 378 nm. We used this property to design a chimeric protein consisting of modified luciferase from Renilla reniformis (RLuc8) and GAF-FP. We showed resonance energy transfer from the substrate, the excited state of which occurs when oxidized by luciferase, to the chromophore GAF-FP–BV in the designed fusion protein. In the absence of an energy acceptor, RLuc8 catalyzes the cleavage of the substrate with the emission of the light with a maximum at 400 nm. At the same time, the energy from the substrate is transferred to the FP chromophore and then emitted in the near-infrared range corresponding to the spectrum of GAF-FP fluorescence in the GAF-FP–RLuc8 chimeric protein. These results open the way for the development of new small near-infrared FPs based on various natural BphPs with a view to their widespread use in cell and molecular biology.     

Contact and Encirclement of Glioma Cells In Vitro Is an Intrinsic Behavior of a Clonal Human Neural Stem Cell Line

Pathotropic neural stem and/or progenitor cells (NSCs) can potentially deliver therapeutic agents to otherwise inaccessible cancers. In glioma, NSCs are found in close contact with tumor cells, raising the possibility that specificity of NSC contact with glioma targets originates in the tumor cells themselves. Alternatively, target preferences may originate, at least in part, in the tumor microenvironment. To better understand mechanisms underlying NSC interactions with glioma cells, we examined NSC-target cell contacts in a highly simplified 3-dimensional peptide hydrogel (Puramatrix) in which cell behaviors can be studied in the relative absence of external cues. HB1.F3 is an immortalized clonal human NSC line extensively characterized in preclinical investigations. To study contact formation between HB1.F3 NSCs and glioma cells, we first examined co-cultures of eGFP-expressing HB1.F3 (HB1.F3.eGFP) NSCs and dsRed-expressing U251 glioma (U251.dsRed) cells. Using confocal microscopy, HB1.F3.eGFP cells were observed contacting or encircling U251.dsRed glioma cells, but never the reverse. Next, examining specificity of these contacts, no significant quantitative differences in either percentages of HB1.F3 NSCs contacting targets, or in the extent of target cell encirclement, were observed when HB1.F3.eGFP cells were presented with various potential target cells (human glioma and breast cancer cell lines, patient-derived brain tumor lines, non-tumor fibroblasts, primary mouse and human astroglial cells, and primary adult and newborn human dermal fibroblasts) except that interactions between HB1.F3 cells did not progress beyond establishing contacts. Finally cytoskeletal mechanisms employed by HB1.F3.eGFP cells varied with the substrate. When migrating in Puramatrix, HB1.F3 NSCs exhibited intermittent process extension followed by soma translocation, while during encirclement their movements were more amoeboid. We conclude that formation of contacts and subsequent encirclement of target cells by HB1.F3 NSCs is an intrinsic property of these NSCs, and that preferential contact formation with tumor cells in vivo must therefore be highly dependent on microenvironmental cues.     

Coral Fluorescent Proteins as Antioxidants

Background

A wide array of fluorescent proteins (FP) is present in anthozoans, although their biochemical characteristics and function in host tissue remain to be determined. Upregulation of FP''s frequently occurs in injured or compromised coral tissue, suggesting a potential role of coral FPs in host stress responses.

Methodology/Principal Findings

The presence of FPs was determined and quantified for a subsample of seven healthy Caribbean coral species using spectral emission analysis of tissue extracts. FP concentration was correlated with the in vivo antioxidant potential of the tissue extracts by quantifying the hydrogen peroxide (H₂O₂) scavenging rates. FPs of the seven species varied in both type and abundance and demonstrated a positive correlation between H₂O₂ scavenging rate and FP concentration. To validate this data, the H₂O₂ scavenging rates of four pure scleractinian FPs, cyan (CFP), green (GFP), red (RFP) and chromoprotein (CP), and their mutant counterparts (without chromophores), were investigated. In vitro, each FP scavenged H₂O₂ with the most efficient being CP followed by equivalent activity of CFP and RFP. Scavenging was significantly higher in all mutant counterparts.

Conclusions/Significance

Both naturally occurring and pure coral FPs have significant H₂O₂ scavenging activity. The higher scavenging rate of RFP and the CP in vitro is consistent with observed increases of these specific FPs in areas of compromised coral tissue. However, the greater scavenging ability of the mutant counterparts suggests additional roles of scleractinian FPs, potentially pertaining to their color. This study documents H₂O₂ scavenging of scleractinian FPs, a novel biochemical characteristic, both in vivo across multiple species and in vitro with purified proteins. These data support a role for FPs in coral stress and immune responses and highlights the multi-functionality of these conspicuous proteins.     

An Orthotopic Model of Serous Ovarian Cancer in Immunocompetent Mice for in vivo Tumor Imaging and Monitoring of Tumor Immune Responses

Background: Ovarian cancer is generally diagnosed at an advanced stage where the case/fatality ratio is high and thus remains the most lethal of all gynecologic malignancies among US women ^1,2,3. Serous tumors are the most widespread forms of ovarian cancer and ^4,5 the Tg-MISIIR-TAg transgenic represents the only mouse model that spontaneously develops this type of tumors. Tg-MISIIR-TAg mice express SV40 transforming region under control of the Mullerian Inhibitory Substance type II Receptor (MISIIR) gene promoter ⁶. Additional transgenic lines have been identified that express the SV40 TAg transgene, but do not develop ovarian tumors. Non-tumor prone mice exhibit typical lifespan for C57Bl/6 mice and are fertile. These mice can be used as syngeneic allograft recipients for tumor cells isolated from Tg-MISIIR-TAg-DR26 mice. Objective: Although tumor imaging is possible ⁷, early detection of deep tumors is challenging in small living animals. To enable preclinical studies in an immunologically intact animal model for serous ovarian cancer, we describe a syngeneic mouse model for this type of ovarian cancer that permits in vivo imaging, studies of the tumor microenvironment and tumor immune responses. Methods: We first derived a TAg+ mouse cancer cell line (MOV1) from a spontaneous ovarian tumor harvested in a 26 week-old DR26 Tg-MISIIR-TAg female. Then, we stably transduced MOV1 cells with TurboFP635 Lentivirus mammalian vector that encodes Katushka, a far-red mutant of the red fluorescent protein from sea anemone Entacmaea quadricolor with excitation/emission maxima at 588/635 nm ^8,9,10. We orthotopically implanted MOV1^Kat in the ovary ^11,12,13,14 of non-tumor prone Tg-MISIIR-TAg female mice. Tumor progression was followed by in vivo optical imaging and tumor microenvironment was analyzed by immunohistochemistry. Results: Orthotopically implanted MOV1^Kat cells developed serous ovarian tumors. MOV1^Kat tumors could be visualized by in vivo imaging up to three weeks after implantation (fig. 1) and were infiltrated with leukocytes, as observed in human ovarian cancers ¹⁵ (fig. 2). Conclusions: We describe an orthotopic model of ovarian cancer suitable for in vivo imaging of early tumors due to the high pH-stability and photostability of Katushka in deep tissues. We propose the use of this novel syngeneic model of serous ovarian cancer for in vivo imaging studies and monitoring of tumor immune responses and immunotherapies.Download video file.^{(63M, mov)}     

Very Bright Green Fluorescent Proteins from the Pontellid Copepod Pontella mimocerami

Background

Fluorescent proteins (FP) homologous to the green fluorescent protein (GFP) from the jellyfish Aequorea victoria have revolutionized biomedical research due to their usefulness as genetically encoded fluorescent labels. Fluorescent proteins from copepods are particularly promising due to their high brightness and rapid fluorescence development.

Results

Here we report two novel FPs from Pontella mimocerami (Copepoda, Calanoida, Pontellidae), which were identified via fluorescence screening of a bacterial cDNA expression library prepared from the whole-body total RNA of the animal. The proteins are very similar in sequence and spectroscopic properties. They possess high molar extinction coefficients (79,000 M⁻¹ cm⁻) and quantum yields (0.92), which make them more than two-fold brighter than the most common FP marker, EGFP. Both proteins form oligomers, which we were able to counteract to some extent by mutagenesis of the N-terminal region; however, this particular modification resulted in substantial drop in brightness.

Conclusions

The spectroscopic characteristics of the two P. mimocerami proteins place them among the brightest green FPs ever described. These proteins may therefore become valuable additions to the in vivo imaging toolkit.     

Developing Fast Fluorescent Protein Voltage Sensors by Optimizing FRET Interactions

FRET (Förster Resonance Energy Transfer)-based protein voltage sensors can be useful for monitoring neuronal activity in vivo because the ratio of signals between the donor and acceptor pair reduces common sources of noise such as heart beat artifacts. We improved the performance of FRET based genetically encoded Fluorescent Protein (FP) voltage sensors by optimizing the location of donor and acceptor FPs flanking the voltage sensitive domain of the Ciona intestinalis voltage sensitive phosphatase. First, we created 39 different “Nabi1” constructs by positioning the donor FP, UKG, at 8 different locations downstream of the voltage-sensing domain and the acceptor FP, mKO, at 6 positions upstream. Several of these combinations resulted in large voltage dependent signals and relatively fast kinetics. Nabi1 probes responded with signal size up to 11% ΔF/F for a 100 mV depolarization and fast response time constants both for signal activation (~2 ms) and signal decay (~3 ms). We improved expression in neuronal cells by replacing the mKO and UKG FRET pair with Clover (donor FP) and mRuby2 (acceptor FP) to create Nabi2 probes. Nabi2 probes also had large signals and relatively fast time constants in HEK293 cells. In primary neuronal culture, a Nabi2 probe was able to differentiate individual action potentials at 45 Hz.     

Superfolder GFP is fluorescent in oxidizing environments when targeted via the Sec translocon

The ability to study proteins in live cells using genetically encoded fluorescent proteins (FPs) has revolutionized cell biology (1-3). Researchers have created numerous FP biosensors and optimized FPs for specific organisms and subcellular environments in a rainbow of colors (4,5). However, expressing FPs in oxidizing environments such as the eukaryotic endoplasmic reticulum (ER) or the bacterial periplasm can impair folding, thereby preventing fluorescence (6,7). A substantial fraction of enhanced green fluorescent protein (EGFP) oligomerizes to form non-fluorescent mixed disulfides in the ER (6) and EGFP does not fluoresce in the periplasm when targeted via the SecYEG translocon (7). To overcome these obstacles, we exploited the highly efficient folding capability of superfolder GFP (sfGFP) (8). Here, we report sfGFP does not form disulfide-linked oligomers in the ER and maltose-binding protein (MBP) signal sequence (peri)-sfGFP (9) is brightly fluorescent in the periplasm of Escherichia coli. Thus, sfGFP represents an important research tool for studying resident proteins of oxidizing environments.     

Multiplexed FRET to image multiple signaling events in live cells

We report what to our knowledge is a novel approach for simultaneous imaging of two different Förster resonance energy transfer (FRET) sensors in the same cell with minimal spectral cross talk. Previous methods based on spectral ratiometric imaging of the two FRET sensors have been limited by the availability of suitably bright acceptors for the second FRET pair and the spectral cross talk incurred when measuring in four spectral windows. In contrast to spectral ratiometric imaging, fluorescence lifetime imaging (FLIM) requires measurement of the donor fluorescence only and is independent of emission from the acceptor. By combining FLIM-FRET of the novel red-shifted TagRFP/mPlum FRET pair with spectral ratiometric imaging of an ECFP/Venus pair we were thus able to maximize the spectral separation between our chosen fluorophores while at the same time overcoming the low quantum yield of the far red acceptor mPlum. Using this technique, we could read out a TagRFP/mPlum intermolecular FRET sensor for reporting on small Ras GTP-ase activation in live cells after epidermal growth factor stimulation and an ECFP/Venus Cameleon FRET sensor for monitoring calcium transients within the same cells. The combination of spectral ratiometric imaging of ECFP/Venus and high-speed FLIM-FRET of TagRFP/mPlum can thus increase the spectral bandwidth available and provide robust imaging of multiple FRET sensors within the same cell. Furthermore, since FLIM does not require equal stoichiometries of donor and acceptor, this approach can be used to report on both unimolecular FRET biosensors and protein-protein interactions with the same cell.     

Mechanism of ArcLight derived GEVIs involves electrostatic interactions that can affect proton wires

The genetically encoded voltage indicators ArcLight and its derivatives mediate voltage-dependent optical signals by intermolecular, electrostatic interactions between neighboring fluorescent proteins (FPs). A random mutagenesis event placed a negative charge on the exterior of the FP, resulting in a greater than 10-fold improvement of the voltage-dependent optical signal. Repositioning this negative charge on the exterior of the FP reversed the polarity of voltage-dependent optical signals, suggesting the presence of “hot spots” capable of interacting with the negative charge on a neighboring FP, thereby changing the fluorescent output. To explore the potential effect on the chromophore state, voltage-clamp fluorometry was performed with alternating excitation at 390 nm followed by excitation at 470 nm, resulting in several mutants exhibiting voltage-dependent, ratiometric optical signals of opposing polarities. However, the kinetics, voltage ranges, and optimal FP fusion sites were different depending on the wavelength of excitation. These results suggest that the FP has external, electrostatic pathways capable of quenching fluorescence that are wavelength specific. One mutation to the FP (E222H) showed a voltage-dependent increase in fluorescence when excited at 390 nm, indicating the ability to affect the proton wire from the protonated chromophore to the H222 position. ArcLight-derived sensors may therefore offer a novel way to map how conditions external to the β-can structure can affect the fluorescence of the chromophore and transiently affect those pathways via conformational changes mediated by manipulating membrane potential.     

Drug screening assay based on the interaction of intact Keap1 and Nrf2 proteins in cancer cells

Background

The Nrf2–Keap1 interaction is the major regulatory pathway for cytoprotective responses against oxidative and electrophilic stresses. Keap1, a substrate protein of a Cul3-dependent E3 ubiquitin ligase complex, is a negative regulator of Nrf2. The use of chemicals to regulate the interaction between Keap1 and Nrf2 has been proposed as a strategy for the chemoprevention of degenerative diseases and cancers.

A Monomeric Photoconvertible Fluorescent Protein for Imaging of Dynamic Protein Localization

The use of green-to-red photoconvertible fluorescent proteins (FPs) enables researchers to highlight a subcellular population of a fusion protein of interest and to image its dynamics in live cells. In an effort to enrich the arsenal of photoconvertible FPs and to overcome the limitations imposed by the oligomeric structure of natural photoconvertible FPs, we designed and optimized a new monomeric photoconvertible FP. Using monomeric versions of Clavularia sp. cyan FP as template, we employed sequence-alignment-guided design to create a chromophore environment analogous to that shared by known photoconvertible FPs. The designed gene was synthesized and, when expressed in Escherichia coli, found to produce green fluorescent colonies that gradually switched to red after exposure to white light. We subjected this first-generation FP [named mClavGR1 (monomeric Clavularia-derived green-to-red photoconvertible 1)] to a combination of random and targeted mutageneses and screened libraries for efficient photoconversion using a custom-built system for illuminating a 10-cm Petri plate with 405-nm light. Following more than 15 rounds of library creation and screening, we settled on an optimized version, known as mClavGR2, that has eight mutations relative to mClavGR1. Key improvements of mClavGR2 relative to mClavGR1 include a 1.4-fold brighter red species, 1.8-fold higher photoconversion contrast, and dramatically improved chromophore maturation in E. coli. The monomeric status of mClavGR2 has been demonstrated by gel-filtration chromatography and the functional expression of a variety of mClavGR2 chimeras in mammalian cells. Furthermore, we have exploited mClavGR2 to determine the diffusion kinetics of the membrane protein intercellular adhesion molecule 1 both when the membrane is in contact with a T-lymphocyte expressing leukocyte-function-associated antigen 1 and when it is not. These experiments clearly establish that mClavGR2 is well suited for rapid photoconversion of protein subpopulations and subsequent tracking of dynamic changes in localization in living cells.     

<Emphasis Type="Italic">In vivo</Emphasis> fluorescence imaging to assess early therapeutic response to tumor progression in a xenograft cancer model

Bioimaging technology plays an important role in assessment of therapeutic response in cancer therapy. Here, we report a non-invasive monitoring system for measuring tumor growth by in vivo fluorescence imaging. Target cells for xenograft tumor induction were manipulated by cell-surface fluorescence labelling. Fluorescence was clearly detected in vitro and in vivo without affecting cytotoxicity. Anti-tumor efficacy was evaluated by directly measuring the fluorescence signal of a progressive tumor in a xenograft model. This non-invasive in vivo monitoring system can be used to assess the early response to antitumor therapeutics and may be a valuable tool to replace or complement traditional caliper-based methods for preclinical studies.     

Fluorescent proteins for FRET microscopy: monitoring protein interactions in living cells

The discovery and engineering of novel fluorescent proteins (FPs) from diverse organisms is yielding fluorophores with exceptional characteristics for live-cell imaging. In particular, the development of FPs for fluorescence (or F?rster) resonance energy transfer (FRET) microscopy is providing important tools for monitoring dynamic protein interactions inside living cells. The increased interest in FRET microscopy has driven the development of many different methods to measure FRET. However, the interpretation of FRET measurements is complicated by several factors including the high fluorescence background, the potential for photoconversion artifacts and the relatively low dynamic range afforded by this technique. Here, we describe the advantages and disadvantages of four methods commonly used in FRET microscopy. We then discuss the selection of FPs for the different FRET methods, identifying the most useful FP candidates for FRET microscopy. The recent success in expanding the FP color palette offers the opportunity to explore new FRET pairs.     

VenusA206 Dimers Behave Coherently at Room Temperature

Fluorescent proteins (FPs) have revolutionized cell biology by allowing genetic tagging of specific proteins inside living cells. In conjunction with Förster’s resonance energy transfer (FRET) measurements, FP-tagged proteins can be used to study protein-protein interactions and estimate distances between tagged proteins. FRET is mediated by weak Coulombic dipole-dipole coupling of donor and acceptor fluorophores that behave independently, with energy hopping discretely and incoherently between fluorophores. Stronger dipole-dipole coupling can mediate excitonic coupling in which excitation energy is distributed near instantaneously between coherently interacting excited states that behave as a single quantum entity. The interpretation of FP energy transfer measurements to estimate separation often assumes that donors and acceptors are very weakly coupled and therefore use a FRET mechanism. This assumption is considered reasonable as close fluorophore proximity, typically associated with strong excitonic coupling, is limited by the FP β-barrel structure. Furthermore, physiological temperatures promote rapid vibrational dephasing associated with a rapid decoherence of fluorophore-excited states. Recently, FP dephasing times that are 50 times slower than traditional organic fluorophores have been measured, raising the possibility that evolution has shaped FPs to allow stronger than expected coupling under physiological conditions. In this study, we test if excitonic coupling between FPs is possible at physiological temperatures. FRET and excitonic coupling can be distinguished by monitoring spectral changes associated with fluorophore dimerization. The weak coupling mediating FRET should not cause a change in fluorophore absorption, whereas strong excitonic coupling causes Davydov splitting. Circular dichroism spectroscopy revealed Davydov splitting when the yellow FP Venus_A206 dimerizes, and a novel approach combining photon antibunching and fluorescence correlation spectroscopy was used to confirm that the two fluorophores in a Venus_A206 homodimer behave as a single-photon emitter. We conclude that excitonic coupling between Venus_A206 fluorophores is possible at physiological temperatures.