Ratiometric bimolecular beacons for the sensitive detection of RNA in single living cells

Numerous studies have utilized molecular beacons (MBs) to image RNA expression in living cells; however, there is growing evidence that the sensitivity of RNA detection is significantly hampered by their propensity to emit false-positive signals. To overcome these limitations, we have developed a new RNA imaging probe called ratiometric bimolecular beacon (RBMB), which combines functional elements of both conventional MBs and siRNA. Analogous to MBs, RBMBs elicit a fluorescent reporter signal upon hybridization to complementary RNA. In addition, an siRNA-like double-stranded domain is used to facilitate nuclear export. Accordingly, live-cell fluorescent imaging showed that RBMBs are localized predominantly in the cytoplasm, whereas MBs are sequestered into the nucleus. The retention of RBMBs within the cytoplasmic compartment led to >15-fold reduction in false-positive signals and a significantly higher signal-to-background compared with MBs. The RBMBs were also designed to possess an optically distinct reference fluorophore that remains unquenched regardless of probe confirmation. This reference dye not only provided a means to track RBMB localization, but also allowed single cell measurements of RBMB fluorescence to be corrected for variations in probe delivery. Combined, these attributes enabled RBMBs to exhibit an improved sensitivity for RNA detection in living cells.     

Sub-cellular trafficking and functionality of 2′-O-methyl and 2′-O-methyl-phosphorothioate molecular beacons

Molecular beacons (MBs) have shown great potential for the imaging of RNAs within single living cells; however, the ability to perform accurate measurements of RNA expression can be hampered by false-positives resulting from nonspecific interactions and/or nuclease degradation. These false-positives could potentially be avoided by introducing chemically modified oligonucleotides into the MB design. In this study, fluorescence microscopy experiments were performed to elucidate the subcellular trafficking, false-positive signal generation, and functionality of 2′-O-methyl (2Me) and 2′-O-methyl-phosphorothioate (2MePS) MBs. The 2Me MBs exhibited rapid nuclear sequestration and a gradual increase in fluorescence over time, with nearly 50% of the MBs being opened nonspecifically within 24 h. In contrast, the 2MePS MBs elicited an instantaneous increase in false-positives, corresponding to ∼5–10% of the MBs being open, but little increase was observed over the next 24 h. Moreover, trafficking to the nucleus was slower. After 24 h, both MBs were localized in the nucleus and lysosomal compartments, but only the 2MePS MBs were still functional. When the MBs were retained in the cytoplasm, via conjugation to NeutrAvidin, a significant reduction in false-positives and improvement in functionality was observed. Overall, these results have significant implications for the design and applications of MBs for intracellular RNA measurement.     

Slow non-specific accumulation of 2′-deoxy and 2′-O-methyl oligonucleotide probes at mitochondria in live cells

Molecular beacons (MBs) have the potential to provide a powerful tool for rapid RNA detection in living cells, as well as monitoring the dynamics of RNA expression in response to external stimuli. To exploit this potential, it is necessary to distinguish true signal from background signal due to non-specific interactions. Here, we show that, when cyanine-dye labeled 2′-deoxy and 2′-O-methyl oligonucleotide probes are inside living cells for >5 h, most of their signals co-localize with mitochondrial staining. These probes include random-sequence MB, dye-labeled single-strand linear oligonucleotide and dye-labeled double-stranded oligonucleotide. Using carbonyl cyanide m-chlorophenyl hydrazone treatment, we found that the non-specific accumulation of oligonucleotide probes at mitochondria was driven by mitochondrial membrane potential. We further demonstrated that the dye-labeled oligonucleotide probes were likely on/near the surface of mitochondria but not inside mitochondrial inner membrane. Interestingly, oligonucleotides probes labeled respectively with Alexa Fluor 488 and Alexa Fluor 546 did not accumulate at mitochondria, suggesting that the non-specific interaction between dye-labeled ODN probes and mitochondria is dye-specific. These results may help design and optimize fluorescence imaging probes for long-time RNA detection and monitoring in living cells.     

Target accessibility and signal specificity in live-cell detection of BMP-4 mRNA using molecular beacons

The ability to visualize mRNA in single living cells and monitor in real-time the changes of mRNA level and localization can provide unprecedented opportunities for biological and disease studies. However, the mRNA detection specificity and sensitivity are critically dependent on the selection of target sequences and their accessibility. We carried out an extensive study of the target accessibility of BMP-4 mRNA using 10 different designs of molecular beacons (MBs), and identified the optimal beacon design. Specifically, for MB design 1 and 8 (MB1 and MB8), the fluorescent intensities from BMP-4 mRNA correlated well with the GFP signal after upregulating BMP-4 and co-expressing GFP using adenovirus, and the knockdown of BMP-4 mRNA using siRNA significantly reduced the beacon signals, demonstrating detection specificity. The beacon specificity was further confirmed using blocking RNA and in situ hybridization. We found that fluorescence signal from MBs depends critically on target sequences; the target sequences corresponding to siRNA sites may not be good sites for beacon-based mRNA detection, and vice versa. Possible beacon design rules are identified and approaches for enhancing target accessibility are discussed. This has significant implications to MB design for live cell mRNA detection.     

Visualization and detection of infectious coxsackievirus replication using a combined cell culture-molecular beacon assay

Rapid detection of infectious viruses is of central importance for public health risk assessment. By directly visualizing newly synthesized viral RNA with molecular beacons (MBs), we have developed a generalized method for the rapid and sensitive detection of infectious viruses from cell culture. An MB, CVB1, specifically targeting the 5' noncoding region of the enterovirus genome was designed and synthesized. Introduction of MB CVB1 into permeabilized cells highly infected with coxsackievirus B6 resulted in brightly fluorescent cells that can be easily visualized with a fluorescence microscope. In contrast, no detectable signal was observed with noninfected cells or with nonspecific MBs. The number of fluorescent cells also increased in a dose-responsive manner, enabling the direct quantification of infectious viral dosages by direct counting of fluorescent foci. As little as 1 PFU of infectious coxsackievirus B6 was detected within 6 h postinfection. When combined with nuclease-resistant MBs, this method could be useful not only for the real-time detection of infectious viruses but is also useful to study the life cycle of viral processing in vivo.     

Visualization and Detection of Infectious Coxsackievirus Replication Using a Combined Cell Culture-Molecular Beacon Assay

Rapid detection of infectious viruses is of central importance for public health risk assessment. By directly visualizing newly synthesized viral RNA with molecular beacons (MBs), we have developed a generalized method for the rapid and sensitive detection of infectious viruses from cell culture. An MB, CVB1, specifically targeting the 5′ noncoding region of the enterovirus genome was designed and synthesized. Introduction of MB CVB1 into permeabilized cells highly infected with coxsackievirus B6 resulted in brightly fluorescent cells that can be easily visualized with a fluorescence microscope. In contrast, no detectable signal was observed with noninfected cells or with nonspecific MBs. The number of fluorescent cells also increased in a dose-responsive manner, enabling the direct quantification of infectious viral dosages by direct counting of fluorescent foci. As little as 1 PFU of infectious coxsackievirus B6 was detected within 6 h postinfection. When combined with nuclease-resistant MBs, this method could be useful not only for the real-time detection of infectious viruses but is also useful to study the life cycle of viral processing in vivo.     

Translation inhibition reveals interaction of 2′-deoxy and 2′-O-methyl molecular beacons with mRNA targets in living cells

Understanding the interaction between oligonucleotide probes and RNA targets in living cells is important for biological and clinical studies of gene expression in vivo. Here, we demonstrate that starvation of cells and translation inhibition by blocking the mTOR or PI-3 kinase pathway could significantly reduce the fluorescence signal from 2′-deoxy molecular beacons (MBs) targeting K-ras and GAPDH mRNAs in living cells. However, the intensity and localization of fluorescence signal from MBs targeting nontranslated 28S rRNA remained the same in normal and translation-inhibited cells. We also found that, in targeting K-ras and GAPDH mRNAs, the signal level from MBs with 2′-O-methyl backbone did not change when translation was repressed. Taken together, our findings suggest that MBs with DNA backbone hybridize preferentially with mRNAs in their translational state in living cells, whereas those with 2′-O-methyl chemistry tend to hybridize to mRNA targets in both translational and nontranslational states. This work may thus provide a significant insight into probe design for detection of RNA molecules in living cells and RNA biology.     

A transformer of molecular beacon for sensitive and real-time detection of phosphatases with effective inhibition of the false positive signals

Molecular beacons (MBs) have shown great potential in measurement of enzyme activities. However, currently available methods for monitoring of phosphatases only use MBs as a signal reporter. Extra substrates for the phosphatases are needed to hybridize to the MB either as a primer or as a template. Moreover, few MB-based methods have been used to detect enzyme activities in real biological samples due to insufficient sensitivity or false positive interference signals caused by nonspecific nucleases. In this work, a novel type of fluorescent probe was designed and synthesized for monitoring of phosphatases by integrating the DNA substrate and the signaling structures into a single molecule. Such a new design not only significantly simplified the probing system and greatly enhanced the sensitivity, but also offered a practical way to guard against the false-positive signal problems in the application to real samples. The unique design of the assay format should be widely applicable to many other enzymatic assays using oligonucleotide fluorescent probes.     

Molecular beacons: nucleic acid hybridization and emerging applications.

Molecular beacons (MBs) are a novel class of nucleic acid probes that become fluorescent when bound to a complementary sequence. Because of this characteristic, coupled with the sequence specificity of nucleic acid hybridization and the sensitivity of fluorescence techniques, MBs are very useful probes for a variety of applications requiring the detection of DNA or RNA. We survey various applications of MBs, including the monitoring of DNA triplex formation, and describe recent developments in MB design that enhance their sensitivity.     

Specific detection of RNA molecules by fluorescent in situ hybridization in living cells

The antisense therapeutic strategy makes the assumption that sequence-specific hybridization of an oligonucleotide to its target can take place in living cells. The present work provides a new method for the detection of intracellular RNA molecules using in situ hybridization on living cells. The first step consisted in designing nonperturbant conditions for cell permeabilization using streptolysin O. In a second step, intracellular hybridization specificity was evaluated by incorporating various types of fluorescently labeled nucleic acid probes (plasmids, oligonucleotides). Due to its high expression level, the 28S ribosomal RNA was retained as a model. Results showed that: (1) no significant cell death was observed after permeabilization; (2) on living cells, 28S RNA specific probes provided bright nucleoli and low cytoplasmic signal; (3) control probes did not lead to significant fluorescent staining; and (4) comparison of signals obtained on living and fixed cells showed a colocalization of observed fluorescence. These results indicate the feasibility of specific hybridization of labeled nucleic acid probes under living conditions, after a simple and efficient permeabilization step. This new detection method is of interest for investigating the dynamics of distribution of various gene products in living cells, under normal or pathological conditions.Abbreviations PI propidium iodide - SLO streptolysin O     

Discrimination of the false-positive signals of molecular beacons by combination of heat inactivation and using single walled carbon nanotubes

Molecular beacons (MBs) have been extensively used for real-time monitoring of RNA/DNA and protein molecules. However, such versatility also brings about multiple sources of positive signals. Moreover, the covalently attached quencher or fluorophore may even be cleaved from the strand by the exonucleases, followed by complete degradation of the probe. These undesirable false-positive signals (FPSs) have seriously limited the application of MBs to detect real world samples. In this paper, we propose a novel and efficient approach for discrimination of FPSs of MBs due to non-specific MB-protein interactions and nuclease degradation by combination of heat inactivation and using single walled carbon nanotubes (SWNTs). The mechanisms of different DNA-protein interactions that are responsible for the generation of FPSs of MBs were investigated in detail. The proposed strategy can quickly identify the possible sources of FPSs caused by mechanisms other than hybridization in detecting real samples, which would be very helpful in choosing a proper way to modify the structure of the MBs or using a specific inhibitor. The established method was successfully applied to verify the FPSs in the measurement of a plant tissue sample.     

Efficient cytosolic delivery of molecular beacon conjugates and flow cytometric analysis of target RNA

Fluorescent microscopy experiments show that when 2'-O-methyl-modified molecular beacons (MBs) are introduced into NIH/3T3 cells, they elicit a nonspecific signal in the nucleus. This false-positive signal can be avoided by conjugating MBs to macromolecules (e.g. NeutrAvidin) that prevent nuclear sequestration, but the presence of a macromolecule makes efficient cytosolic delivery of these probes challenging. In this study, we explored various methods including TAT peptide, Streptolysin O and microporation for delivering NeutrAvidin-conjugates into the cytosol of living cells. Surprisingly, all of these strategies led to entrapment of the conjugates within lysosomes within 24 h. When the conjugates were pegylated, to help prevent intracellular recognition, only microporation led to a uniform cytosolic distribution. Microporation also yielded a transfection efficiency of 93% and an average viability of 86%. When cells microporated with MB-NeutrAvidin conjugates were examined via flow cytometry, the signal-to-background was found to be more than 3 times higher and the sensitivity nearly five times higher than unconjugated MBs. Overall, the present study introduces an improved methodology for the high-throughput detection of RNA at the single cell level.     

Spectroscopic investigation of a FRET molecular beacon containing two fluorophores for probing DNA/RNA sequences.

We report the design, synthesis, and characterization of a molecular beacon (MB) consisting of two fluorescent dyes (Alexa 488 and RedX) for DNA and RNA analysis. In the absence of the target DNA or RNA the MB is in its stem-closed form and shows efficient energy transfer from the donor (Alexa) to the acceptor (RedX), generating mostly fluorescence from RedX. In the presence of the complementary target DNA the MB opened efficiently, hybridizes with the target DNA, and energy transfer is blocked in the stem-open form. This attachment to the target generates a fluorescence signature, which is clearly distinguishable from the fluorescence signature of the stem-closed form, allowing for ratiometric analysis of the fluorescence signal. In addition to steady-state fluorescence analysis, time resolved fluorescence (ps time range) and fluorescence depolarization studies were performed. We show that fluorescence lifetime and fluorescence depolarization measurements are useful analytical tools to optimize the MB design.     

Detection of hepatitis a virus by using a combined cell culture-molecular beacon assay

Rapid and efficient methods for the detection and quantification of infectious viruses are required for public health risk assessment. Current methods to detect infectious viruses are based on mammalian cell culture and rely on the production of visible cytopathic effects (CPE). For hepatitis A virus (HAV), viral replication in cell culture has been reported to be nonlytic and relatively slow. It may take more than 1 week to reach the maximum production and subsequent visualization of CPE. A molecular beacon (MB), H1, specifically targeting a 20-bp 5' noncoding region of HAV, was designed and synthesized. MB H1 was introduced into fixed and permeabilized fetal rhesus monkey kidney (FRhK-4) cells infected with HAV strain HM-175. Upon hybridizing with the viral mRNA, fluorescent cells were visualized easily under a fluorescence microscope. Discernible fluorescence was detected only in infected cells by using the specific MB H1. A nonspecific MB, which was not complementary to the viral RNA sequence, produced no visible fluorescence signal. This MB-based fluorescence assay enabled the direct counting of fluorescent cells and could achieve a detection limit of 1 PFU at 6 h postinfection, demonstrating a significant improvement in viral quantification over current infectivity assays.     

The cytoskeletal system of nucleated erythrocytes. I. Composition and function of major elements

We have studied the dogfish erythrocyte cytoskeletal system, which consists of a marginal band of microtubules (MB) and trans-marginal band material (TBM). The TBM appeared in whole mounts as a rough irregular network and in thin sections as a surface-delimiting layer completely enclosing nucleus and MB. In cells incubated at 0 degrees C for 30 min or more, the MB disappeared but the TBM remained. MB reassembly occurred with rewarming, and was inhibited by colchicine. Flattened elliptical erythrocyte morphology was retained even when MBs were absent. Total solubilization of MB and TBM at low pH, or dissolution of whole anucleate cytoskeletons, yielded components comigrating with actin, spectrin, and tubulin standards during gel electrophoresis. Mass-isolated MBs, exhibiting ribbonlike construction apparently maintained by cross-bridges, contained four polypeptides in the tubulin region of the gel. Only these four bands were noticeably increased in the soluble phase obtained from cells with 0 degrees C- disassembled MBs. The best isolated MB preparations contained tubulin but no components comigrating with high molecular weight microtubule- associated proteins, spectrin, or actin. Actin and spectrin therefore appear to be major TBM constituents, with tubulin localized in the MB. The results are interpreted in terms of an actin- and spectrin- containing subsurface cytoskeletal layer (TBM), related to that of mammalian erythrocytes, which maintains cell shape in the absence of MBs. Observations on abnormal pointed erythrocytes containing similarly pointed MBs indicate further that the MB can deform the TBM from within so as to alter cell shape. MBs may function in this manner during normal cellular morphogenesis and during blood flow in vivo.     

Visualization of protein interactions in living Caenorhabditis elegans using bimolecular fluorescence complementation analysis

The bimolecular fluorescence complementation (BiFC) assay is a powerful tool for visualizing and identifying protein interactions in living cells. This assay is based on the principle of protein-fragment complementation, using two nonfluorescent fragments derived from fluorescent proteins. When two fragments are brought together in living cells by tethering each to one of a pair of interacting proteins, fluorescence is restored. Here, we provide a protocol for a Venus-based BiFC assay to visualize protein interactions in the living nematode, Caenorhabditis elegans. We discuss how to design appropriate C. elegans BiFC cloning vectors to enable visualization of protein interactions using either inducible heat shock promoters or native promoters; transform the constructs into worms by microinjection; and analyze and interpret the resulting data. When expression of BiFC fusion proteins is induced by heat shock, the fluorescent signals can be visualized as early as 30 min after induction and last for 24 h in transgenic animals. The entire procedure takes 2-3 weeks to complete.