A Lucifer‐Based Environment‐Sensitive Fluorescent PNA Probe for Imaging Poly(A) RNAs

Fluorescence‐based oligonucleotide (ON) hybridization probes greatly aid the detection and profiling of RNA sequences in cells. However, certain limitations such as target accessibility and hybridization efficiency in cellular environments hamper their broad application because RNAs can form complex and stable structures. In this context, we have developed a robust hybridization probe suitable for imaging RNA in cells by combining the properties of 1) a new microenvironment‐sensitive fluorescent nucleobase analogue, obtained by attaching the Lucifer chromophore ( 1,8‐naphthalimide) at the 5‐position of uracil, and 2) a peptide nucleic acid (PNA) capable of forming stable hybrids with RNA. The fluorescence of the PNA base analogue labeled with the Lucifer chromophore, when incorporated into PNA oligomers and hybridized to complementary and mismatched ONs, is highly responsive to its neighboring base environment. Notably, the PNA base reports the presence of an adenine repeat in an RNA ON with reasonable enhancement in fluorescence. This feature of the emissive analogue enabled the construction of a poly(T) PNA probe for the efficient visualization of polyadenylated [poly(A)] RNAs in cells—poly(A) being an important motif that plays vital roles in the lifecycle of many types of RNA. Our results demonstrate that such responsive fluorescent nucleobase analogues, when judiciously placed in PNA oligomers, could generate useful hybridization probes to detect nucleic acid sequences in cells and also to image them.     

2′‐Bispyrene‐Modified 2′‐O‐Methyl RNA Probes as Useful Tools for the Detection of RNA: Synthesis,Fluorescent Properties,and Duplex Stability

The synthesis and properties two series of new 2′‐O‐methyl RNA probes, each containing a single insertion of a 2′‐bispyrenylmethylphosphorodiamidate derivative of a nucleotide (U, C, A, and G), are described. As demonstrated by UV melting studies, the probes form stable complexes with model RNAs and DNAs. Significant increases (up to 21‐fold) in pyrene excimer fluorescence intensity were observed upon binding of most of the probes with complementary RNAs, but not with DNAs. The fluorescence spectra are independent of the nature of the modified nucleotides. The nucleotides on the 5′‐side of the modified nucleotide have no effect on the fluorescence spectra, whereas the natures of the two nucleotides on the 3′‐side are important: CC, CG, and UC dinucleotide units on the 3′‐side of the modified nucleotide provide the maximum increases in excimer fluorescence intensity. This study suggests that these 2′‐bispyrene‐labeled 2′‐O‐methyl RNA probes might be useful tools for detection of RNAs.     

A Dual Reporter System for Detecting RNA Interactions in Bacterial Cells

Detecting RNA–partner interactions in cells is often difficult due to a lack of suitable tools. Here we describe a dual reporter system capable of detecting intracellular interactions in which one of the partners is an RNA. The system utilizes two fluorescent proteins with similar maturation rates but distinct spectral properties, specifically cyan fluorescent protein (CFP) and yellow fluorescent protein (YFP). By placing the CFP gene upstream and the YFP gene downstream of an RNA gene of interest, the production of YFP becomes sensitive to RNA–partner interaction, whereas the synthesis of CFP is not disturbed. Therefore, the RNA–partner interaction can be simply measured by the change in the ratio of fluorescence of YFP over CFP. The utility of our approach is demonstrated through verification of three known RNA–partner interactions in the model bacterium Escherichia coli. Our two‐reporter strategy should be broadly useful to the study of RNA‐targeted interactions in bacteria.     

Fluoride detection with a colorimetric and fluorescent dual-mode chemosensor

We designed a colorimetric and fluorescent dual-mode chemosensor ADM ((E)-2-(((2-amino-4,5-dichlorophenyl)imino)methyl)-6-methoxyphenol) for detecting fluoride (F⁻). The sensor ADM can detect F⁻ by colour and fluorescence changes. The colour change is from colourless to yellow, and the fluorescence change is a yellow turn-on. With the results of Job plot and electrospray ionisation mass spectrometry, the reaction of F⁻ and ADM turned out to be a 1:1 binding. The detection limits for F⁻ of ADM were 5.00 μM in ultraviolet–visible and 4.16 μM in fluorescence. The detecting process of F⁻ by ADM was demonstrated by ultraviolet–visible and fluorescent titrations, electrospray ionisation mass spectrometry, proton nuclear magnetic resonance titration and theoretical calculations.     

TaqMan实时定量RT-PCR检测轮状病毒G4型

目的应用基于TaqMan探针的实时定量RT-PCR检测轮状病毒(Rotavirus,RV)G4型VP7基因。方法从G1、G2、G3和G4型轮状病毒Vero细胞培养物中提取病毒总RNA,分别进行RT-PCR和实时定量RT-PCR,检测引物及探针的特异性;构建含轮状病毒G4型VP7基因的质粒,制备RNA参考品,绘制实时定量RT-PCR标准曲线;验证实时定量RT-PCR的灵敏度和精密性;对5个轮状病毒G4型培养物及G1、G2和G3型各3个病毒培养物进行检测,分析其实际应用性。结果以轮状病毒G4型VP7基因引物和探针只能从G4型轮状病毒总RNA中扩增出目的基因或检测到荧光信号的扩增,未在G1、G2、G3型轮状病毒总RNA中扩增出目的基因或检测到荧光信号的扩增;在2.34×107～2.34×103拷贝/μl范围内,反应扩增效率大于90%,R2大于0.98;该方法可检出100数量级的RNA样品,且试验内及试验间变异系数分别小于2.5%和4%;用建立的实时定量RT-PCR只检出5个轮状病毒G4型样品,而G1、G2、G3型样品均未检出。结论 TaqMan实时定量RT-PCR是一种灵敏度较高、特异性和精密性良好的定量检测轮状病毒G4型的方法。     

A novel coumarin‐based fluorescent probe for selective detection of cysteine over homocysteine

A coumarin‐based fluorescent probe containing both acrylate moiety and an allyl substituent was developed for distinguishing cysteine from homocysteine. The maximum absorption wavelength of the probe showed a bathochromic shift upon addition of cysteine and the colour changed from colourless to yellow. The maximum fluorescence emission at 462 nm of the probe was dramatically enhanced upon addition of cysteine in aqueous solution. In HEPES buffer (pH = 7.4, EtOH/H₂O = 9:1, v/v), both of the fluorescence emission bands of the probe at ca. 390 and 462 nm were intensely enhanced upon the addition of cysteine, while other amino acids, namely, homocysteine, asparaginic acid, methionine, glycine, phenylalaninase, valine, tryptophan, serine, glutamic acid and glutathione, did not cause a remarkable change. The probe can be used for selectively colorimetric and ratiometric fluorescent detection of cysteine over homocysteine and other common amino acids in both organic media and aqueous solution. The concentration of cysteine can be estimated by titration of the probe in aqueous solution, and the detection limit of the probe towards cysteine was 2 μmol/L.     

The natural fluorescence of wool

Wool may be excited by both mid-and near-u.v. radiation, emitting fluorescence. The extent of visible fluorescence depends on the origin of the wool and the degree of weathering, (the tips of the fibres being more fluorescent than the roots) and chemical modification. In particular oxidative treatments such as chlorination of shrink-resist procedures or peroxide bleaching processes increase the intensity of visible fluorescence but decrease the intensity of u.v. fluorescence (emission maximum at about 350 nm). It is proposed that the presence of these fluorescent chromophores in the fibre relates to the susceptibility of wool to yellow on exposure to light.     

Novel (phenylethynyl)pyrene-LNA constructs for fluorescence SNP sensing in polymorphic nucleic acid targets

We describe fluorescent oligonucleotide probes labeled with novel (phenylethynyl)pyrene dyes attached to locked nucleic acids. Furthermore, we prove the utility of these probes for the effective detection of single-nucleotide polymorphisms in natural nucleic acids. High-affinity hybridization of the probes and excellent fluorescence responses to single-base mismatches in DNA/RNA targets are demonstrated in model dual-probe and doubly labeled probe formats. This stimulated us to develop two diagnostic systems for the homogeneous detection of a drug-resistance-causing mutation in HIV-1 protease cDNA and RNA gene fragments. Target sequences were obtained by analysis of 200 clinical samples from patients currently receiving anti-HIV/AIDS combination therapy at the Russian Federal AIDS Center. Using these fluorescent oligonucleotides, we were able to detect the target mutation despite all the challenges of the natural targets, that is, the presence of additional mutations, neighboring sequence variation, and low target concentration, which typically reduce binding and effectiveness of sensing by fluorescent oligonucleotides.     

Nucleic Acid Detection through RNA-Guided Protease Activity in Type III-E CRISPR-Cas Systems

RNA-guided protease activity was recently discovered in the type III-E CRISPR-Cas systems (Craspase), providing a novel platform for engineering a protein probe instead of the commonly used nucleic acid probe in nucleic acid detection assays. Here, by adapting a fluorescence readout technique using the affinity- and fluorescent protein dual-tagged Csx30 protein substrate, we have established an assay monitoring Csx30 cleavage by target ssRNA-activated Craspase. Four Craspase-based nucleic acid detection systems for genes from severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), norovirus, and the influenza virus (IFV) were reconstituted with demonstrated specificity. The assay could reliably detect target ssRNAs at concentrations down to 25 pM, which could be further improved approximately 15 000-fold (ca. 2 fM) by incorporating a recombinase polymerase isothermal preamplification step. Importantly, the species-specific substrate cleavage specificity of Craspase enabled multiplexed diagnosis, as demonstrated by the reconstituted composite systems for simultaneous detection of two genes from the same virus (SARS-CoV-2, spike and nsp12) or two types of viruses (SARS-CoV-2 and IFV). The assay could be further expanded by diversifying the fluorescent tags in the substrate and including Craspase systems from various species, thus potentially providing an easily adaptable platform for clinical diagnosis.     

Monitoring of Apoptosis in 3D Cell Cultures by FRET and Light Sheet Fluorescence Microscopy

Non-radiative cell membrane associated Förster Resonance Energy Transfer (FRET) from an enhanced cyan fluorescent protein (ECFP) to an enhanced yellow fluorescent protein (EYFP) is used for detection of apoptosis in 3-dimensional cell cultures. FRET is visualized in multi-cellular tumor spheroids by light sheet based fluorescence microscopy in combination with microspectral analysis and fluorescence lifetime imaging (FLIM). Upon application of staurosporine and to some extent after treatment with phorbol-12-myristate-13-acetate (PMA), a specific activator of protein kinase c, the caspase-3 sensitive peptide linker DEVD is cleaved. This results in a reduction of acceptor (EYFP) fluorescence as well as a prolongation of the fluorescence lifetime of the donor (ECFP). Fluorescence spectra and lifetimes may, therefore, be used for monitoring of apoptosis in a realistic 3-dimensional system, while light sheet based microscopy appears appropriate for 3D imaging at low light exposure.     

The Role of Flexibility in the Rational Design of Modularly Assembled Ligands Targeting the RNAs that Cause the Myotonic Dystrophies

Modularly assembled ligands were designed to target the RNAs that cause two currently untreatable neuromuscular disorders, myotonic dystrophy types 1 (DM1) and 2 (DM2). DM1 is caused by an expanded repeating sequence of CUG, and DM2 is caused by expanded CCUG repeats. Both are present in noncoding regions and fold into hairpins with either repeating 1×1 nucleotide UU (DM1) or 2×2 nucleotide 5′‐CU/3′‐UC (DM2) internal loops separated by two GC pairs. The repeats are toxic because they sequester the RNA splicing regulator muscleblind‐like 1 protein (MBNL1). Rational design of ligands targeting these RNAs was enabled by a database of RNA motif–ligand partners compiled by using two‐dimensional combinatorial screening (2DCS). One 2DCS study found that the 6′′‐azido‐kanamycin A module binds internal loops similar to those found in DM1 and DM2. In order to further enhance affinity and specificity, the ligand was assembled on a peptoid backbone to precisely control valency and the distance between ligand modules. Designed compounds are more potent and specific binders to the toxic RNAs than MBNL1 and inhibit the formation of the RNA–protein complexes with nanomolar IC₅₀ values. This study shows that three important factors govern potent inhibition: 1) the surface area sequestered by the assembled ligands; 2) the spacing between ligand modules since a longer distance is required to target DM2 RNAs than DM1 RNAs; and 3) flexibility in the modular assembly scaffold used to display the RNA‐binding module. These results have impacts on the general design of assembled ligands targeting RNAs present in genomic sequence.     

Molecular Glue for RNA: Regulating RNA Structure and Function through Synthetic RNA Binding Molecules

We introduce the concept of molecular glues for RNA, in which specific RNA-binding small molecules induce designed structural changes in target functional RNAs, resulting in modulation of the functions. (Z)-NCTS is an RNA-mismatch-binding small molecule that recognizes 5′-r(XGG)-3′/5′-r(XGG)-3′ sequences (X=U or A) and acts as a molecular glue for RNA. The binding of (Z)-NCTS brings two distinct 5′-r(XGG)-3′ domains into contact with each other, and this can result in higher-order structural changes of target RNAs. We applied (Z)-NCTS to induce the formation of a proposed tertiary structure of a ribozyme together with activation of RNA-cleaving ability. The concept of a molecular glue could inspire new small-molecule-based strategies for regulating biological functions: a synthetic small molecule targeting functional RNAs could regulate the RNA structure and function.     

A Simple DNAzyme-Based Fluorescent Assay for Klebsiella pneumoniae

Pathogenic bacteria pose a serious threat to public health, and the rapid and cost-effective detection of such bacteria remains a major challenge. Herein, we present a DNAzyme-based fluorescent paper sensor for Klebsiella pneumoniae. The DNAzyme was generated by an in vitro selection technique to cleave a fluorogenic DNA–RNA chimeric substrate in the presence of K. pneumoniae. The DNAzyme was printed on a paper substrate in a 96-well format to serve as mix-and-read fluorescent assay that exhibits a limit of detection (LOD) 10⁵ CFUs mL⁻¹. Evaluated with 20 strains of clinical bacterial isolates, the DNAzyme produced the desired fluorescence signal with the samples of K. pneumoniae, regardless of their source or drug resistance. The assay is simple to use, rapid, inexpensive, and avoids the complex procedures of sample preparation and equipment. We believe that this DNAzyme-based fluorescent assay has potential for practical applications to identify K. pneumoniae.     

Allosteric Probe Recognition Initiated Cascade Transcription Amplification for Sensitive Analysis of Exosomes

Sensitive and accurate analysis of exosomes is important for many biological processes including as a biomarker for cerebral venous thrombosis (CVT) diagnosis and therapy. Herein, we established a sensitive and specific exosome detection approach based on target recognition initiated cascade signal amplification. In this method, an allosteric probe was designed with a hairpin structure for specific recognition of the exosome followed by signal amplification. After the cascade signal amplification process, spinach RNA sequences bind to DFHBI ((Z)-4-(3,5-difluoro-4-hydroxybenzylidene)-1,2-dimethyl-1H-imidazol-5(4H)-one) to produce enhanced fluorescence signal (approximate 2000 fold than that of inactive DFHBI). Compared with former proposed exosome detection techniques, this method exhibited a comparable detection range, but with an easy-to-design toolbox. Therefore, we believe that the proposed approach holds great potential for exosome based early diagnosis and prognosis of disease.     

Labeling small RNAs through chemical ligation at the 5' terminus: enzyme-free or combined with enzymatic 3'-labeling

The discovery of small RNAs such as microRNAs (miRNAs), small interfering RNAs (siRNAs), or Piwi-associated RNAs (piRNAs) has led to new challenges in the selective detection of RNAs. Many noncoding RNAs act as post-translational regulators of gene expression and are involved in the regulation of cell proliferation or apoptosis, but are difficult to amplify, label, and detect. Standard microarray detection procedures involve pre-hybridization labeling or enzymatic 3'-labeling by polymerase-catalyzed extension. Dual labeling would improve the fidelity of detection, but no polymerases for 5'-extension are known. Here we report a novel labeling method for RNAs bearing natural 5'-phosphate groups, such as miRNAs, based on enzyme-free ligation of a biotin- or fluorophore-labeled oligonucleotide to the 5' termini. The method uses in situ activation of the natural 5'-phosphate groups in these RNAs and was optimized to give near-quantitative conversion in solution. With use of biotin- or fluorophore-bearing labeling strands, different miRNA sequences were detected on microarrays with little background fluorescence. In combination with an established method of enzymatic on-chip labeling at the 3' termini, highly selective detection of related miRNAs was achieved by dual recognition at both termini, even in the case of miRNAs differing in only one nucleotide.     

Optical sensor for aliphatic amines based on the simultaneous colorimetric and fluorescence responses of smart textile

The pH indicator proposed is a water‐soluble dye based on benzo[de]antracen‐7‐one. Dissolving in buffered aqueous solution, it changes color from yellow to orange and in the mean time decreases its fluorescence emission as a function of the amine concentration. Viscose fabric, dyed with the same dye has been investigated as a new reversible colorimetric and fluorescent sensor material for ammonia and aliphatic amines in buffered solution. The high value of the dye pK_a and the influence of the textile matrix on the selective detection of dimethylamine compared to ammonia, trimethylamine, and metylamine have been studied. The different response of the solution and textile matrix as well as the optical analyses both as a color change and a fluorescence emission have been discussed. The advantage of this sensor is the fact that depending on the analytical problem to be solved and the available instrumentation it can be used either as a fluorogenic or as a chromogenic chemosensor. In addition, the textile sensor is characterized by facile fabrication, low cost, sensibility, and reproducibility. © 2007 Wiley Periodicals, Inc. J Appl Polym Sci 2007     

A Fluorescent RNA Forced‐Intercalation Probe as a Pan‐Selective Marker for Influenza A Virus Infection

The influenza A virus (IAV) genome is segmented into eight viral ribonucleoproteins, each expressing a negatively oriented viral RNA (vRNA). Along the infection cycle, highly abundant single‐stranded small viral RNAs (svRNA) are transcribed in a segment‐specific manner. The sequences of svRNAs and of the vRNA 5′‐ends are identical and highly conserved among all IAV strains. Here, we demonstrate that these sequences can be used as a target for a pan‐selective sensor of IAV infection. To this end, we used a complementary fluorescent forced‐intercalation RNA (IAV QB‐FIT) probe with a single locked nucleic acid substitution to increase brightness. We demonstrated by fluorescence in situ hybridization (FISH) that this probe is suitable and easy to use to detect infection of different cell types by a broad variety of avian, porcine, and human IAV strains, but not by other influenza virus types. IAV QB‐FIT also provides a useful tool to characterize different infection states of the host cell.     

Controlling the Fluorescence of Benzofuran‐Modified Uracil Residues in Oligonucleotides by Triple‐Helix Formation

We developed fluorescent turn‐on probes containing a fluorescent nucleoside, 5‐(benzofuran‐2‐yl)deoxyuridine (dU^BF) or 5‐(3‐methylbenzofuran‐2‐yl)deoxyuridine (dU^MBF), for the detection of single‐stranded DNA or RNA by utilizing DNA triplex formation. Fluorescence measurements revealed that the probe containing dU^MBF achieved superior fluorescence enhancement than that containing dU^BF. NMR and fluorescence analyses indicated that the fluorescence intensity increased upon triplex formation partly as a consequence of a conformational change at the bond between the 3‐methylbenzofuran and uracil rings. In addition, it is suggested that the microenvironment around the 3‐methylbenzofuran ring contributed to the fluorescence enhancement. Further, we developed a method for detecting RNA by rolling circular amplification in combination with triplex‐induced fluorescence enhancement of the oligonucleotide probe containing dU^MBF.     

A Cautionary Note on the Use of Split-YFP/BiFC in Plant Protein-Protein Interaction Studies

Since its introduction in plants 10 years ago, the bimolecular fluorescence complementation (BiFC) method, or split-YFP (yellow fluorescent protein), has gained popularity within the plant biology field as a method to study protein-protein interactions. BiFC is based on the restoration of fluorescence after the two non-fluorescent halves of a fluorescent protein are brought together by a protein-protein interaction event. The major drawback of BiFC is that the fluorescent protein halves are prone to self-assembly independent of a protein-protein interaction event. To circumvent this problem, several modifications of the technique have been suggested, but these modifications have not lead to improvements in plant BiFC protocols. Therefore, it remains crucial to include appropriate internal controls. Our literature survey of recent BiFC studies in plants shows that most studies use inappropriate controls, and a qualitative rather than quantitative read-out of fluorescence. Therefore, we provide a cautionary note and beginner’s guideline for the setup of BiFC experiments, discussing each step of the protocol, including vector choice, plant expression systems, negative controls, and signal detection. In addition, we present our experience with BiFC with respect to self-assembly, peptide linkers, and incubation temperature. With this note, we aim to provide a guideline that will improve the quality of plant BiFC experiments.