Hg2+‐selective ratiometric and colorimetric probe based on dansyl–rhodamine and its staining function in cell imaging

A new ratiometric probe composed of a dansyl–rhodamine dyad for the detection of Hg²⁺ via fluorescence resonance energy transfer was designed and synthesized. Rhodamine, dansyl chloride, and hydrazide were selected as the acceptor, donor, and reaction site, respectively. It displayed high selectivity and sensitivity to Hg²⁺ with obvious colour change and fluorescence change due to Hg²⁺‐assisted hydrolysis of rhodamine hydrazide. A good linear relationship ranging from 0 to 16 μM and 0–28 μM for the Hg²⁺ concentration was found based on absorbance and fluorescence assay, respectively. Detection limits of absorbance and fluorescence for Hg²⁺ were calculated to be 1.22 μM and 9.10 μM, respectively.     

A rhodamine‐triazole fluorescent chemodosimeter for Cu2+ detection and its application in bioimaging

A rhodamine‐based fluorescent chemodosimeter rhodamine hydrazide‐triazole (RHT) tethered with a triazole moiety was developed for Cu²⁺ detection. In aqueous medium, the RHT probe exhibited high selectivity and sensitivity toward Cu²⁺ among other metal ions. The addition of Cu²⁺ triggered a fluorescence emission of RHT by 384‐fold (Φ = 0.33) based on a ring‐opening process and a subsequent hydrolysis reaction. Moreover, RHT also showed a selective colorimetric response toward Cu²⁺ from colorless solution to pink, readily observed with the naked eye. The limit of detection of RHT for Cu²⁺ was calculated to be 1 nM (0.06 ppb). RHT was successfully demonstrated to detect Cu²⁺ in Chang liver cells by confocal fluorescence microscopy.     

The application of anti‐ESAT‐6 monoclonal antibody fluorescent probe in ex vivo near‐infrared fluorescence imaging in mice with pulmonary tuberculosis

Here, we aimed to assess the feasibility of anti‐ESAT‐6 monoclonal antibody (mAb) coupling with IR783 and rhodamine fluorescent probe in the detection of ESAT‐6 expression in tuberculosis tissue of mice using near‐infrared fluorescence imaging. IR783 and rhodamine were conjugated to the anti‐ESAT‐6 mAb or IgG. Mice in the experimental group were injected with fluorescence‐labeled mAb probe, and mice in the control group were injected with fluorescence‐labeled non‐specific IgG antibody. Twenty‐four hours later, the lung tissue of mice was examined using ex vivo near‐infrared fluorescence imaging. In addition, the contrast‐to‐noise ratio (CNR) was calculated by measuring the signal intensities of the pulmonary lesions, normal lung tissue and background noise. The frozen lung tissue section was examined under fluorescence microscopy and compared with hemoxylin and eosin (HE) staining. The ex vivo near‐infrared fluorescence imaging showed that the fluorescence signal in the lung tuberculosis lesions in the experimental group was significantly enhanced, whereas there was only a weak fluorescence signal or even no fluorescence signal in the control group. CNR values were 64.40 ± 7.02 (n = 6) and 8.75 ± 3.87 (n = 6), respectively (t = 17.01, p < 0.001). The fluorescence accumulation distribution detected under fluorescence microscopy was consistent with HE staining of the tuberculosis region. In conclusion, anti‐ESAT‐6 mAb fluorescent probe could target and be applied in specific ex vivo imaging of mice tuberculosis, and may be of further use in tuberculosis in living mice. Copyright © 2013 John Wiley & Sons, Ltd.     

Ratiometric fluorescent detection of Cu2+ based on dual‐emission ZIF‐8@rhodamine‐B nanocomposites

Zeolitic imidazolate framework‐8 (ZIF‐8) loading rhodamine‐B (ZIF‐8@rhodamine‐B) nanocomposites was proposed and used as ratiometric fluorescent sensor to detect copper(II) ion (Cu²⁺). Scanning electron microscopy, Fourier transform infrared spectroscopy, X‐ray powder diffraction, nitrogen adsorption/desorption isotherms and fluorescence emission spectroscopy were employed to characterize the ZIF‐8@rhodamine‐B nanocomposites. The results showed the rhodamine‐B was successfully assembled on ZIF‐8 based on the π‐π interaction and the hydrogen bond between the nitrogen atom of ZIF‐8 and –COOH of rhodamine‐B. The as‐obtained ZIF‐8@rhodamine‐B nanocomposites were octahedron with size about 150–200 nm, had good water dispersion, and exhibited the characteristic fluorescence emission of ZIF‐8 at 335 nm and rhodamine‐B at 575 nm. The Cu²⁺ could quench fluorescence of ZIF‐8 rather than rhodamine‐B. The ZIF‐8 not only acted as the template to assemble rhodamine‐B, but also was employed as the signal fluorescence together with the fluorescence of rhodamine‐B as the reference to construct a novel ratiometric fluorescent sensor to detect Cu²⁺. The resulted ZIF‐8@rhodamine‐B nanocomposite fluorescence probe showed good linear range (68.4 nM to 125 μM) with a low detection limit (22.8 nM) for Cu²⁺ combined with good sensitivity and selectivity. The work also provides a better way to design ratiometric fluorescent sensors from ZIF‐8 and other fluorescent molecules.     

A fast‐responsive fluorescent probe for sulfite and its bioimaging

A turn‐on fluorescent probe Coumarin‐SO2 based on a nucleophilic addition reaction was developed for the rapid detection of SO₃^2– in aqueous media. The probe Coumarin‐SO2 displays excellent water solubility, fast response, highly sensitivity and highly selectivity over other biological related species. More importantly, living cell imaging experiments indicate the feasibility of using the probe for the detection of SO₃^2– in biological systems. Copyright © 2015 John Wiley & Sons, Ltd.     

A high‐throughput detection method for invasive fruit fly (Diptera: Tephritidae) species based on microfluidic dynamic array

Invasive species can be detrimental to a nation's ecology, economy and human health. Rapid and accurate diagnostics are critical to limit the establishment and spread of exotic organisms. The increasing rate of biological invasions relative to the taxonomic expertise available generates a demand for high‐throughput, DNA‐based diagnostics methods for identification. We designed species‐specific qPCR primer and probe combinations for 27 economically important tephritidae species in six genera (Anastrepha, Bactrocera, Carpomya, Ceratitis, Dacus and Rhagoletis) based on 935 COI DNA barcode haplotypes from 181 fruit fly species publically available in BOLD, and then tested the specificity for each primer pair and probe through qPCR of 35 of those species. We then developed a standardization reaction system for detecting the 27 target species based on a microfluidic dynamic array and also applied the method to identify unknown immature samples from port interceptions and field monitoring. This method led to a specific and simultaneous detection for all 27 species in 7.5 h, using only 0.2 μL of reaction system in each reaction chamber. The approach successfully discriminated among species within complexes that had genetic similarities of up to 98.48%, while it also identified all immature samples consistent with the subsequent results of morphological examination of adults which were reared from larvae of cohorts from the same samples. We present an accurate, rapid and high‐throughput innovative approach for detecting fruit flies of quarantine concern. This is a new method which has broad potential to be one of international standards for plant quarantine and invasive species detection.     

A coumarin‐based fluorescent turn‐on probe for detection of biothiols in vitro

A novel fluorescent probe (CA‐N) was designed and synthesized for detection of biothiols. CA‐N displayed a strong fluorescence in the presence of biothiols with high sensitivity, and the mechanism for detection biothiols was based on the Michael addition reaction of a thiol group to α,β‐unsaturated ketones. CA‐N showed low detection limit for cysteine (Cys), homocysteine (Hcy), and glutathione (GSH), which were calculated as 3.16, 0.19 and 5.15 μM, respectively. At the same time, CA‐N exhibited high selectivity toward biothiols compared with other biological amino acids. In vitro cell experiments proved that CA‐N had no cytotoxicity, high cell permeability and could be employed in living cell imaging for biothiols. Copyright © 2015 John Wiley & Sons, Ltd.     

A turn‐on luminescence probe for highly selective detection of an anthrax biomarker

Highly selective detection of Bacillus anthrax spores has attracted worldwide attention because Bacillus anthrax spores not only are harmful to the health of human beings and animals, but also can be used as biological warfare agents. Here, we report a simple platform by mixing EuCl₃·6H₂O and sodium polyacrylate in aqueous solution and further investigate its luminescence response towards Bacillus anthrax biomarker dipicolinic acid (DPA) as a turn‐on luminescence probe. Importantly, our probe has good sensitivity, lower detection limit, excellent selectivity as well as great anti‐interference ability due to the great luminescence enhancement of Eu³⁺. Moreover, a test paper is constructed to realize the purpose of portable detection. These results indicate that our probe is an excellent candidate for sensing DPA.     

Development of novel mass spectrometric methods for identifying HOCl‐induced modifications to proteins

Protein oxidation is thought to contribute to a number of inflammatory diseases, hence the development of sensitive and specific analytical techniques to detect oxidative PTMs (oxPTMs) in biological samples is highly desirable. Precursor ion scanning for fragment ions of oxidized amino acid residues was investigated as a label‐free MS approach to mapping specific oxPTMs in a complex mixture of proteins. Using HOCl‐oxidized lysozyme as a model system, it was found that the immonium ions of oxidized tyrosine and tryptophan formed in MS² analysis could not be used as diagnostic ions, owing to the occurrence of isobaric fragment ions from unmodified peptides. Using a double quadrupole linear ion trap mass spectrometer, precursor ion scanning was combined with detection of MS³ fragment ions from the immonium ions and collisionally‐activated decomposition peptide sequencing to achieve selectivity for the oxPTMs. For chlorotyrosine, the immonium ion at 170.1 m/z fragmented to yield diagnostic ions at 153.1, 134.1, and 125.1 m/z, and the hydroxytyrosine immonium ion at 152.1 m/z gave diagnostic ions at 135.1 and 107.1 m/z. Selective MS³ fragment ions were also identified for 2‐hydroxytryptophan and 5‐hydroxytryptophan. The method was used successfully to map these oxPTMs in a mixture of nine proteins that had been treated with HOCl, thereby demonstrating its potential for application to complex biological samples.     

Rapid detection and discrimination of fabaviruses by flow‐through hybridisation with genus‐ and species‐specific riboprobes

Viruses cause significant damage in agricultural crops worldwide. Disease management requires sensitive and specific tools for virus detection and identification. Also, detection techniques need to be rapid to keep pace with the continuous emergence of new viral diseases. The genus Fabavirus is composed of five viruses infecting many economically important crops worldwide. This research describes the development of a procedure based on flow‐through hybridisation (FTH), which is faster than and as sensitive as conventional hybridisation for virus detection in tissue‐prints from infected plants. Six digoxigenin‐labelled RNA probes were synthesised with two levels of specificity: (a) five specific for each viral species within this genus, and (b) a genus‐specific probe that hybridises with a nucleotide sequence signature only found in the 5′‐untranslated region of the genus Fabavirus, which is the first of this type reported for plant viruses. The new procedure developed is useful for rapid detection and discrimination of the five fabaviruses identified so far and opens the possibility of discovering new species of this genus.     

A rhodamine‐based fluorescent probe for Cu(II) determination in aqueous solution

An ‘off–on’ rhodamine‐based fluorescence probe for the selective detection of Cu(II) has been designed, exploiting the guest‐induced structure transform mechanism. This system shows a sharp Cu(II)‐selective fluorescence enhancement response in an aqueous system under physiological pH, and possesses high selectivity against a background of environmentally and biologically relevant metal ions. Under optimum conditions, the fluorescence intensity enhancement of this system is linearly proportional to the Cu(II) concentration from 50 nM to 6.0 μM with a detection limit of 29 nM. Copyright © 2014 John Wiley & Sons, Ltd.     

Effects of inactivation methods on the analysis of Bacillus atrophaeus endospores using real‐time PCR and MALDI‐TOF‐MS

A wide range of analytical methods are available for the detection and identification of biological warfare agents. These technologies are often hampered in their performance when the inactivated samples are analyzed. To work with pathogens outside of biosafety level 3 laboratories, a complete inactivation is mandatory when appropriate protection equipment is unavailable. When methods of inactivation are used, the detection of bacteria becomes more difficult. In contrast to measuring viable organisms, inactivation steps can have a massive impact on the intrinsic cellular information. This study examined the effects of autoclaving and chemical inactivation methods on Bacillus spores using biological warfare detection setups like real‐time PCR and MALDI‐TOF‐MS. Here, the inactivation of Bacillus atrophaeus spores with formaldehyde, which is a suggested model for biological warfare spore agents, was compared with other inactivation reagents like Wofasteril^®E400, a commercially available decontaminant based on peroxyacetic acid. With Wofasteril^®E400 the critical factor of inactivation time was reduced to about 15 min and a limit of detection of 8500 spores by PCR was still measurable using five‐times‐washed spores. It has also been shown that MALDI‐TOF‐MS peak information can be hampered by inactivation methods.     

Rhodamine-based fluorogenic probe for imaging biological thiol

We have developed a new fluorescent probe for biological thiol. The probe was synthesized by the modification of the 2,4-dinitrobenzenesulfonyl group with rhodamine 110. The selective detection of thiol species such as cysteine or glutathione was achieved in biological conditions. Moreover, the probe was successfully applied to the imaging of thiol species in living human cells.     

Development of a Real‐time Fluorescence Loop‐mediated Isothermal Amplification Assay for Detection of Burkholderia gladioli pv. alliicola

Burkholderia gladioli pv. alliicola is a causal agent of rot on a wide range of hosts including onion and tulip. It is one of quarantine phytopathogenic bacteria in China. To reduce the economic losses associated with this pathogen, simple and rapid detection methods are needed. In this study, an efficient loop‐mediated isothermal amplification (LAMP) assay with a real‐time fluorometer was developed. The analysis of 16S‐23S rRNA intergenic transcribed spacer (ITS) sequences showed considerable variability between different Burkholderia species and B. gradioli pathovars. A set of LAMP primers was designed based on the ITS region. The sensitivity and specificity of the developed assay were evaluated at the optimal temperature of 65°C. The primers were specific for B. gladioli pv. alliicola and did not react to strains of others species and other pathovars in the species B. gladioli. The sensitivity of the real‐time LAMP assay was 1 fg DNA which was 100 times higher than that of conventional PCR. The method was verified by testing natural samples and inoculated onion seeds, and it showed effectiveness. The real‐time LAMP assay established in this study is an effective method for detection of B. gladioli pv. alliicola.     

Preparation of pH‐stimuli‐responsive PEG–TGA/TGH‐capped CdTe QDs and their application in cell labeling

A pH‐sensitive and double functional nanoprobe was designed and synthesized in a water‐soluble system using thioglycolic acid (TGA) and mercapto‐acetohydrazide (TGH) as the stabilizers. TGA is biocompatible because the carboxyl group is easily linked to biological macromolecules. At the same time, the hydrazide on TGH reacts with the aldehyde on poly(ethylene glycol) (PEG) and forms a hydrazone bond. The hydrazone bond ruptured at specific pH values and exhibited pH‐stimuli‐responsive characteristics. As an optical imaging probe, the PEG–TGA/TGH‐capped CdTe quantum dots (QDs) had high quality, with a fluorescence efficiency of 25–30%, and remained stable for at least five months. This pH‐responsive factor can be used for the effective release of CdTe QDs under the acidic interstitial extracellular environment of tumor cells. This allows the prepared pH‐stimuli‐responsive nanoprobes to show fluorescence signals for use in cancer cell imaging. Copyright © 2014 John Wiley & Sons, Ltd.     

Molecular characterisation and relative incidence of bean‐ and soybean‐infecting begomoviruses in northwestern Argentina

Recent studies identified three begomoviruses infecting soybean and bean crops in northwestern (NW) Argentina, bean golden mosaic virus (BGMV), a virus with high capsid protein identity with Sida mottle virus (SiMoV) and a possible new viral species (isolate A). Analysis of complete DNA‐A sequences confirmed that isolate A represents a new viral species for which the authors propose the name soybean blistering mosaic virus (SbBMV), whereas the SiMoV‐like virus is actually an isolate of tomato yellow spot virus (ToYSV). Molecular hybridisation‐based detection of the three begomoviruses was accomplished using a general probe obtained by mixing full‐length DNA‐A clones of the three begomoviruses and specific probes comprising part of the common region of each viral genome. These probes were used to test samples collected in NW Argentina from 2004 through 2007. Fifty‐three percent of the bean samples were infected with BGMV, 11.5% with ToYSV and 9% with SbBMV. For soybean samples, 33% were infected with SbBMV and 18% with ToYSV. BGMV was not detected in soybean. ToYSV was also detected in the wild species Abutilon theophrasti.     

The synthesis and modification of highly fluorescent carbon quantum dots for reversible detection of water‐soluble phosphonate‐1‐hydroxyethane‐1,1‐diphosphonic acid by fluorescence spectroscopy

Photoluminescent (PL) carbon quantum dots (CQDs) were prepared successfully using a facile and green procedure. They exhibited striking blue fluorescence and excellent optical properties, with a quantum yield as high as 61.44%. Due to the fluorescence quenching effect and the stronger complexing ability of the phosphoric acid group of 1‐hydroxyethane‐1,1‐diphosphonic acid (HEDP) to Fe³⁺ , CQDs doped with Fe³⁺ were adequately constructed as an efficient and sensitive fluorescent probe for HEDP‐specific sensing. The proposed fluorescent probe had a sensitive and rapid response in the range 5–70 μ M. Furthermore, quantitative molecular surface (QMS) analysis based on the Multiwfn program was applied to explore the complexation mode of HEDP and metal ions. The distribution of electrostatic potential (ESP), average local ionization energy (ALIE), the minimum value points and the position of the lone pair electrons on the surface of molecular van der Waals were further determined. More strikingly, this experiment achieved the quantitative detection of water‐soluble phosphonate‐HEDP, for the first time using fluorescence spectrometry. It has been proved to be an effective and intuitive sensing method for the detection of HEDP in real samples.     

Sensitive detection of strong acidic condition by a novel rhodamine‐based fluorescent pH chemosensor

A novel rhodamine‐based fluorescent pH probe responding to extremely low pH values has been synthesized and characterized. This probe showed an excellent photophysical response to pH on the basis that the colorless spirocyclic structure under basic conditions opened to a colored and highly fluorescent form under extreme acidity. The quantitative relationship between fluorescence intensity and pH value (1.75–2.62) was consistent with the equilibrium equation pH = pKa + log[(I_max – I)/(I – I_min)]. This sensitive pH probe was also characterized with good reversibility and no interaction with interfering metal ions, and was successfully applied to image Escherichia coli under strong acidity. Copyright © 2015 John Wiley & Sons, Ltd.     

Improved DNA‐FISH for cytometric detection of Candida spp

Aims: We developed improved methods for DNA‐based fluorescence in situ hybridization (FISH) for rapid detection of Candida spp. and Candida albicans via flow cytometry. Methods and Results: Two previously reported C. albicans‐targeted DNA probes were evaluated against whole cells of C. albicans and related Candida species using a rapid, high‐temperature hybridization protocol. One probe (CalB2208) was shown for the first time to be suitable as a FISH probe. Although cell labelling for both probes was relatively bright, we were able to substantially improve our results by altering fixation and hybridization conditions. For fixation, a 60 : 40 mixture of 10% buffered formalin and ethanol was most effective. Probe intensity was improved as much as ten‐fold through the use of unlabelled helper probes, and buffer containing 0·9 mol l^?1 NaCl plus 10% formamide yielded the best hybridizations for both probe/helper cocktails. Although optimal labelling occurred with longer hybridizations, we found that C. albicans could be completely differentiated from the nontarget yeast Rhodotorula glutinis after only 15 min using the brightest probe (Calb‐1249) and that a formal washing step was not required. Specificities of probe/helper cocktails under optimal conditions were determined using a panel of target and nontarget cell types, including four strains of Candida dubliniensis. Calb‐1249 cross‐reacted slightly with Candida parapsilosis and strongly with both Candida tropicalis and C. dubliniensis. In contrast, we found that CalB2208 was exclusive for C. albicans. The molecular basis of this specificity was confirmed by DNA sequencing. Conclusions: We describe DNA probe‐based approaches for rapid and bright labelling of Candida spp. and for specific labelling of C. albicans without cross‐reaction with C. dubliniensis. Our work improves upon previously described methods. Significance and Impact of the Study: The methods described here for rapid FISH‐based detection of Candida spp. may have applications in both clinical and food microbiology.