Rapid detection of Salmonella in milk by a nuclear magnetic resonance biosensor based on the streptavidin-biotin system and O-carboxymethyl chitosan target gadolinium probe.

Rapid and sensitive detection of foodborne pathogens is of great importance for food safety. Here, a set of nuclear magnetic resonance (NMR) biosensors based on a O-carboxymethyl chitosan target gadolinium (Gd) probe was developed to quickly detect Salmonella in milk by combining NMR technology and bioimmunotechnology with membrane filtration technology. First, O-carboxymethyl chitosan (O-CMC) was biotinylated to prepare biotinylated O-carboxymethyl chitosan (biotin-O-CMC) through amide reaction, and biotinylated magnetic complexes (biotin-O-CMC-Gd) were obtained by using O-CMC, which has strong chelating adsorption on Gd. The target probe was obtained by combining biotin-O-CMC-Gd with the biotinylated antibody (biotin-antibody) via streptavidin (SA) by introducing the SA-biotin system. Then, Salmonella was captured by the target probe through antigen-antibody interaction. Finally, NMR was used to measure the longitudinal relaxation time (T1) of the filtrate collected by membrane filtration. This NMR biosensor with good specificity and high efficiency can detect Salmonella with the sensitivity of 1.8 × 103 cfu/mL within 2 h; in addition, it can realize the detection of complex samples because of its strong anti-interference capability and may open up a new method for rapid detection of Salmonella, which has a great application potential.

The SNAG Domain of Insm1 Regulates Pancreatic Endocrine Cell Differentiation and Represses ß- to δ-Cell Transdifferentiation.

The allocation and specification of pancreatic endocrine lineages are tightly regulated by transcription factors. Disturbances in differentiation of these lineages contribute to the development of various metabolic diseases, including diabetes. The insulinoma-associated protein 1 (Insm1), which encodes a protein containing one SNAG domain and five zinc fingers, plays essential roles in pancreatic endocrine cell differentiation and in mature ß-cell function. In the current study, we compared the differentiation of pancreatic endocrine cells between Insm1 null and Insm1 SNAG domain mutants (Insm1delSNAG) to explore the specific function of the SNAG domain of Insm1. We show that the δ-cell number is increased in Insm1delSNAG but not in Insm1 null mutants as compared with the control mice. We also show a less severe reduction of the ß-cell number in Insm1delSNAG as that in Insm1 null mutants. In addition, similar deficits are observed in α-, PP, and ε-cells in Insm1delSNAG and Insm1 null mutants. We further identified that the increased δ-cell number is due to ß- to δ-cell transdifferentiation. Mechanistically, the SNAG domain of Insm1 interacts with Lsd1, the demethylase of H3K4me1/2. Mutation in the SNAG domain of Insm1 results in impaired recruitment of Lsd1 and increased H3K4me1/2 levels at hematopoietically expressed homeobox (Hhex) loci that are bound by Insm1, thereby promoting the transcriptional activity of the δ-cell-specific gene Hhex Our study has identified a novel function of the SNAG domain of Insm1 in the regulation of pancreatic endocrine cell differentiation, particularly in the repression of ß- to δ-cell transdifferentiation.

Rapid detection of Salmonella in milk with a nuclear magnetic resonance biosensor based on a streptavidin-biotin system and a polyamidoamine-dendrimer-targeted gadolinium probe.

Rapid and sensitive detection technology is the key to preventing food-borne disease outbreaks. In this study, a low-field nuclear magnetic resonance (NMR) biosensor based on polyamidoamine dendrimers was prepared for the rapid detection of Salmonella in milk. The polyamidoamine dendrimer was biotinylated by amide reaction and chelated to diethylene triamine pentacetate acid and gadolinium to form magnetic complexes. The antibody and magnetic complexes were combined through a streptavidin-biotin system using streptavidin as an intermediate bridge to obtain the immunoprobe. Salmonella was captured by the immunoprobe via antigen-antibody interaction and then separated from the mixture by membrane filtration. Finally, the longitudinal relaxation signal of the filtrate was obtained by NMR. The biosensor had excellent anti-interference capability and could detect Salmonella within 1.5 h at a sensitivity of 103 cfu mL-1. This method based on NMR can realize detection in complex samples and has the potential to be a quick and nondestructive method for detecting target bacteria.

Ratiometric fluorescent 3D DNA walker and catalyzed hairpin assembly for determination of microRNA.

Using 6-carboxyfluorescein (FAM) and tetramethyl rhodamine (TAMRA) as fluorescent signals a ratiometric fluorescent three-dimensional (3D) DNA walker based on a catalytic hairpin assembly (CHA) reaction for microRNA-122 detection was constructed. This method uses CHA reaction triggered indirectly by the target to mediate the 3D DNA walker operation to amplify the signal. The dual emission ratio fluorescent signal with a single excitation wavelength was used as the signal output. This strategy combines DNA walker with CHA reaction and proportional fluorescence signal output methods, which can effectively reduce the background fluorescence signal and the risk of generating false-positive signals. Thus, the impact of environmental factors on the experiment is reduced, thereby obtaining reliable and stable experimental results. It uses the fluorescence excitation wavelength of 488 nm and the maximum fluorescence emission wavelength of 520 nm and 580 nm, respectively. It has a good linear response at a microRNA concentration range of 156.0 pM ~ 7.00 nM and a detection limit of 42.94 pM. This strategy has been successfully applied to detect microRNAs in spiked serum samples. Graphical abstract Schematic representation of three-dimensional (3D) DNA walker constructed using catalytic hairpin self-assembly reaction (CHA)-assisted amplification and ratiometric fluorescence signal output for the detection of miRNA-122 closely related to hepatitis.

Detection of microRNA using enzyme-assisted amplifying and DNA-templated silver nanoclusters signal-off fluorescence bioassay.

A Simple and fast analysis strategy of fluorescence quenching based on DNA-templated silver nanoclusters was developed for detection of miR-122 related to diseases such as human liver. We used Exo III to cleave the silver cluster template and assist in the DNA-RNA complex cycle. When the target is absent, the silver cluster template remains intact, and DNA-AgNCs are generated under the action of AgNO3/NaBH4, producing a strong background fluorescence signal. Once the target is added, the site of the Exo III occurs after a series of hybridization cycles, the Exo III acts, the template DNA is continuously hydrolyzed, and the fluorescence intensity of the system is significantly reduced. By comparing the changes in the fluorescence signal, we found that this strategy has good sensitivity and the detection limit is as low as 84.0 pM. The strategy also has excellent discriminating ability and good selectivity, it can provide a persuasive reference for the early diagnosis of liver cancer and hepatitis.

Fluorometric determination of microRNA-122 by using ExoIII-aided recycling amplification and polythymine induced formation of copper nanoparticles.

The authors describe a method for the determination of microRNA-122 by using terminal deoxynucleotidyl transferase (TdT). It is based on the use of polythymine and exonuclease III-aided cycling amplification. A 3'-phosphorylated hairpin probe 1 (H1) and a hairpin probe 2 (H2) were designed. In the presence of the microRNA, hybridization and enzymatic cleavage will occur and produce lots of 3'-hydroxylated ssDNA which can be tailed by TdT and converted into long polythymine (polyT) sequences. These can be used to synthesize copper nanoparticles (CuNPs) with fluorescence excitation/emission maxima at 350 nm/630 nm. This method shows good selectivity and high sensitivity with a linear response in the 1.00 × 102 fM and 1.00 × 106 fM microRNA concentration range and a 44 fM limit of detection. It was successfully applied to determination of microRNA in spiked serum samples. Graphical abstract A label-free and highly sensitive fluorometric method is described for the assay of microRNA on the basis of target-triggered two-cycle amplification and combining with terminal TdT. It produces a series superlong polyT that can be used for synthesis of copper nanoclusters (CuNCs) displaying red fluorecence.

Haploinsufficiency of Insm1 Impairs Postnatal Baseline ß-Cell Mass.

Baseline ß-cell mass is established during the early postnatal period when ß-cells expand. In this study, we show that heterozygous ablation of Insm1 decreases baseline ß-cell mass and subsequently impairs glucose tolerance. When exposed to a high-fat diet or on an ob/ob background, glucose intolerance was more severe in Insm1+/lacZ mice compared with Insm1+/+ mice, although no further decrease in the ß-cell mass was detected. In islets of early postnatal Insm1+/lacZ mice, the cell cycle was prolonged in ß-cells due to downregulation of the cell cycle gene Ccnd1 Although Insm1 had a low affinity for the Ccnd1 promoter compared with other binding sites, binding affinity was strongly dependent on Insm1 levels. We observed dramatically decreased binding of Insm1 to the Ccnd1 promoter after downregulation of Insm1 expression. Furthermore, downregulation of Ccnd1 resulted in a prolonged cell cycle, and overexpression of Ccnd1 rescued cell cycle abnormalities observed in Insm1-deficient ß-cells. We conclude that decreases in Insm1 interfere with ß-cell specification during the early postnatal period and impair glucose homeostasis during metabolic stress in adults. Insm1 levels are therefore a factor that can influence the development of diabetes.

Studies on the binding of rhaponticin with human serum albumin by molecular spectroscopy, modeling and equilibrium dialysis.

Rhaponticin (RHA) possesses a variety of pharmacological activities including potent antitumor, antitumor-promoting, antithrombotic, antioxidant and vasorelaxant effects. In the solvation effect, RHA exhibited bathochromic shift in emission spectra with the increasing solvent polarity. The binding between RHA and HSA was investigated by molecular spectroscopy combining with modeling and equilibrium dialysis. Fluorescence data showed that the quenching of HSA by RHA was result of forming the complex of RHA-HSA. According to Stern-Volmer equation, the binding parameters between RHA and HSA were determined. The enthalpy change (ΔH) and entropy change (ΔS) were calculated to be -2.75kJmol(-1) and 1.58Jmol(-1)K(-1), indicating that the hydrogen bonds and hydrophobic interactions played a dominant role in the binding. The conformational investigation revealed the α-helical structure was decreased and the polypeptides of HSA were slightly folded upon the addition of RHA. The effect of common ions on the binding between RHA and HSA was also investigated. Furthermore, the result of warfarin displacement site indicated that RHA could bind to the site I of HSA, which was in agreement with the molecular modeling. When excitation wavelength was set at 260 or 355nm, RHA exhibited a fluorescence peak at 390nm, based on which, a simple and rapid fluorimetric method was developed and validated to determine RHA in the equilibrium dialysis. Calibration curves of RHA were linear over the concentration range of 1.1-15.0µM with the detection limits of 0.03µM. Examination of protein binding ability showed that RHA with 8.0µM concentrations in HSA achieved the percent of bound 82.3±2.5%.