Changing Characteristics of Treg/Th17 Cells in the Nasal Mucosa of a Mouse Model of Allergic Rhinitis and the Effect of Intervention with Anti-IL-17 Antibody.

BACKGROUND: The incidence rate of allergic rhinitis (AR) is on the rise, which seriously affects the quality of life, work efficiency, mental state of patients, and sleeping in AR sleep. This experiment aimed to investigate the changes in Treg/Th17 cells in the nasal mucosa of an AR mouse model and the intervention effect of an Anti-IL-17 antibody. METHODS: A mouse model of AR was induced by intraperitoneal ovalbumin (OVA) injection for sensitization and stimulation with nasal drops. The times of rubbing, sneezing, and symptomatology scores were counted and analyzed. Pathological damage to the nasal mucosa was observed by Hematoxylin-Eosin (HE) staining. Peripheral blood CD4+CD25+CD127- Treg cell levels and the content of Th17 cells were measured by flow cytometry (FCM). ELISA kits were used to detect the levels of relevant cytokines (IL-10 and TGF-ß1) secreted by Treg cells. The intervention effect of Anti-IL-17 antibody was observed by giving Anti-IL-17 antibody treatment. RESULTS: The times of rubbing, sneezing, and symptomatology scores were significantly higher in mice in the OVA group than in the Control group (p < 0.001). The percentage of CD4+CD25+CD127- Treg cells in CD4+CD25+ T cells (p < 0.05) and the levels of IL-10 (p < 0.001) and TGF-ß1 (p < 0.001) were significantly decreased. After OVA induction, the continuity of the nasal mucosa of mice was interrupted, the percentage of Th17 cells, IL-17, and IL-4 levels were increased, and IFN-γ levels were significantly reduced (p < 0.001). And protein expression of RORγt was significantly upregulated (p < 0.001). In addition, all of these results were reversed by Anti-IL-17 antibody treatment, significantly improving AR-related symptoms (p < 0.05). CONCLUSION: Anti-IL-17 antibodies may regulate the body's immune response by promoting CD4+CD25+CD127- Treg cell differentiation, thereby ameliorating the symptoms associated with AR.

An improved density peaks clustering algorithm based on grid screening and mutual neighborhood degree for network anomaly detection.

With the rapid development of network technologies and the increasing amount of network abnormal traffic, network anomaly detection presents challenges. Existing supervised methods cannot detect unknown attack, and unsupervised methods have low anomaly detection accuracy. Here, we propose a clustering-based network anomaly detection model, and then a novel density peaks clustering algorithm DPC-GS-MND based on grid screening and mutual neighborhood degree for network anomaly detection. The DPC-GS-MND algorithm utilizes grid screening to effectively reduce the computational complexity, improves the clustering accuracy through mutual neighborhood degree, and also defines a cluster center decision value for automatically selecting cluster centers. We implement complete experiments on two real-world datasets KDDCup99 and CIC-IDS-2017, and the experimental results demonstrated that the proposed DPC-GS-MND can detect network anomaly traffic with higher accuracy and efficiency. Together, it has a good application prospect in the network anomaly detection system in complex network environments.

Role of Exosomes in Pharyngucutaneous Fistula After Total Laryngectomy.

Pharyngocutaneous fistula is the most common complication after total laryngectomy and is difficult to heal. Although conservative treatment and surgical repair are effective, they often take longer and additional trips to the operating room, which undoubtedly increases the financial burden on patients. Especially in combination with diseases such as diabetes and hypertension, which affect the efficacy of surgery. Adding growth factors into the repair material can promote fibroblast proliferation, angiogenesis, and accelerate wound healing. A substantial number of studies have shown that a type of nanoscale extracellular vesicle, called exosomes, facilitates organization repair by promoting blood vessel production, protein polysaccharides, and collagen deposition, thereby representing a new type of cellular therapy. At present, there is little research on the application of exosomes in pharyngocutaneous fistula regeneration after total laryngectomy. In this review, we summarize the biological characteristics of exosomes and their application in biomedical science, and highlight their application prospects in pharyngocutaneous fistula regeneration after total laryngectomy.

Lipogels: single-lipid-bilayer-enclosed hydrogel spheres.

We have fabricated Lipogels consisting of a single POPC lipid bilayer supported by a micrometer-sized, thermoresponsive, hydrophobically modified (HM), hydrogel sphere. The hydrogel consists of a lightly cross-linked poly(N-isopropylacrylamide) (pNIPAM) core surrounded by a highly cross-linked acrylic acid (AA)-rich p(NIPAM-co-AA) shell. The lipid bilayer was assembled by binding liposomes to HM microgels, followed by several cycles of freeze-thaw. The pNIPAM volume phase transition (VPT) at ∼32 °C was present both before and after hydrophobic modification and after lipid bilayer coating. Fluorescence studies confirmed the fusion of liposomes into a continuous single bilayer. At a temperature above the VPT, it was found that the volume decrease in the hydrogel was coupled to the appearance of highly curved obtrusions of the uncompromised lipid bilayer into the surroundings. It is anticipated that these properties of Lipogels will prove to be useful in drug delivery applications and in fundamental biophysical studies of membranes.

Triggered instability of liposomes bound to hydrophobically modified core-shell PNIPAM hydrogel beads.

The ability to trigger a destabilization of the membrane integrity of liposomes bound to environmentally sensitive hydrophobically modified core-shell hydrogel beads is demonstrated. Hydrogel beads with a core composed of poly(N-isopropylacrylamide) lightly cross-linked with bisacrylamide (BA) (pNIPAM) and a shell composed of NIPAM highly cross-linked with BA and containing varying amounts of acrylic acid (AA) [p(NIPAM-co-AA)] undergo a volume phase transition (VPT) at approximately 32 degrees C, as determined from (1)H magic angle spinning (MAS) NMR, regardless of the AA content of the shell. When the shell was hydrophobically modified with either decylamine or tetradecylamine, binding of extruded large unilamellar vesicles (eLUVs) composed of 1-palmitoyl-2-oleoylphosphatidylcholine (POPC) was quantitative, as determined via fluorescence spectroscopy. Fluorescence microscopy showed that such bound eLUVs did not fuse. Hydrogel-bound eLUV membrane permeability was assessed using (31)P MAS NMR in the presence of the chemical shift agent praseodymium and demonstrated that only at lower degrees of hydrophobic modification of the core-shell hydrogels was eLUV membrane barrier integrity maintained when T < VPT. At a low degree of hydrophobic modification, cycling the temperature above the VPT even for short periods caused the eLUV membranes to become leaky. Hence, eLUV membrane permeability was coupled to the hydrogel VPT, a situation that would be useful in applications requiring triggered release of liposomal contents.

A photostable, pH-invariant fluorescein derivative for single-molecule microscopy.

We herein report the comprehensive characterization of the spectral and single-photon fluorescence properties of a recently synthesized fluorescein derivative and its biotinylated analog. The fluorophore displays significant increases in photostability compared to the known fluorescein label fluorescein isothiocyanate (FITC), as well as superb pH independence. This fluorescein variant has two readily accessible functional groups (aniline NH2 and phenol OH) that can be activated or blocked independently and can serve, for instance, as a fluorescent bridge between two different recognition motifs. Excellent single-photon counting fluorescence data demonstrates that it is also a particularly appropriate probe for single-molecule studies of biological interactions.

The effect of intrachain electrostatic repulsion on conformational disorder and dynamics of the Sic1 protein.

The yeast cyclin-dependent kinase inhibitor Sic1 is a disordered protein that, upon multisite phosphorylation, forms a dynamic complex with the Cdc4 subunit of an SCF ubiquitin ligase. To understand the multisite phosphorylation dependence of the Sic1:Cdc4 interaction, which ultimately leads to a sharp cell cycle transition, the conformational properties of the disordered Sic1 N-terminal targeting region were studied using single-molecule fluorescence spectroscopy. Multiple conformational populations with different sensitivities to charge screening were identified by performing experiments in nondenaturing salts and ionic denaturants. Both the end-to-end distance and the hydrodynamic radius decrease monotonically with increasing the salt concentration, and a rollover of the chain dimensions in high denaturant conditions is observed. The data were fit to the polyelectrolyte binding-screening model, yielding parameters such as the excluded volume of the uncharged chain and the binding constant to denaturant. An overall scaling factor of ∼1.2 was needed for fitting the data, which implies that Sic1 cannot be approximated by a random Gaussian chain. Fluorescence correlation spectroscopy reveals Sic1 structure fluctuations occurring on both fast (10-100 ns) and slow (∼10 ms) time scales, with the fast phase absent in low salt solutions. The results of this study provide direct evidence that long-range intrachain electrostatic repulsions are a significant factor for the conformational landscape of Sic1, and support the role of electrostatics in determining the overall shape and hydrodynamic properties of intrinsically disordered proteins.

On the performance of bioanalytical fluorescence correlation spectroscopy measurements in a multiparameter photon-counting microscope.

Fluorescence correlation spectroscopy (FCS) data acquisition and analysis routines were developed and implemented in a home-built, multiparameter photon-counting microscope. Laser excitation conditions were investigated for two representative fluorescent probes, Rhodamine110 and enhanced green fluorescent protein (EGFP). Reliable local concentrations and diffusion constants were obtained by fitting measured FCS curves, provided that the excitation intensity did not exceed 20% of the saturation level for each fluorophore. Accurate results were obtained from FCS measurements for sample concentrations varying from pM to µM range, as well as for conditions of high background signals. These experimental constraints were found to be determined by characteristics of the detection system and by the saturation behavior of the fluorescent probes. These factors actually limit the average number of photons that can be collected from a single fluorophore passing through the detection volume. The versatility of our setup and the data analysis capabilities were tested by measuring the mobility of EGFP in the nucleus of Drosophila cells under conditions of high concentration and molecular crowding. As a bioanalytical application, we studied by FCS the binding affinity of a novel peptide-based drug to the cancer-regulating STAT3 protein and corroborated the results with fluorescence polarization analysis derived from the same photon data.

Trapping single molecules in liposomes: surface interactions and freeze-thaw effects.

We report on an improved method to encapsulate proteins and other macromolecules inside surface-tethered liposomes to reduce or eliminate environmental interference for single-molecule investigations. These lipid vesicles are large enough for the molecule to experience free diffusion but sufficiently small so that the molecule appears effectively immobile under the fluorescence microscope. Single-molecule fluorescence experiments were used to characterize this anchoring method relative to direct immobilization via biotin-streptavidin linkers. Multidimensional histograms of intensity, polarization, and lifetime revealed that molecules trapped in liposomes display a narrow distribution around a single peak, while the molecules directly immobilized on surface show highly dispersed values for all parameters. By hydrating the lipid film at low volumes, high encapsulation efficiencies can be achieved with ~10 times less biological material than previous protocols. We measured vesicle size distributions and found no significant advantage for using freeze-thaw cycles during vesicle preparation. On the contrary, the temperature jump can induce irreversible damage of fluorophores and it reduces significantly the functionality of proteins, as demonstrated on single-molecule binding experiments on STAT3. Our improved and biologically gentle molecule encapsulation protocol has a great potential for widespread applications in single-molecule fluorescence spectroscopy.

Liposome-hydrogel bead complexes prepared via biotin-avidin conjugation.

Liposomes immobilized onto polymeric hydrogel microbeads have potential advantages both in tissue engineering applications and as drug delivery vehicles. Here we demonstrate, quantify, and optimize lipid vesicle binding to polymeric hydrogel microbeads via the avidin-biotin conjugation system and characterize the stability of the resulting microgel-bound liposomes. Microgels consisting of a copolymer of N-isopropylacrylamide (NIPAM) and acrylic acid (AA), cross-linked with bis-acrylamide, that is, p(NIPAM-co-AA), were biotinylated using aqueous carbodiimide chemistry. Extruded liposomes consisting of 1-palmitoyl-2-oleoyl-phosphatidylcholine (POPC) plus a small fraction of a biotin-derivatized phosphatidylethanolamine (B-PE) were saturated with avidin and allowed to bind to biotinylated hydrogel beads. Using a combination of fluorescence spectroscopy, quenching, and microscopy and 31P NMR static and magic angle spinning (MAS) spectroscopies, we demonstrate conditions for near-quantitative liposome binding to p(NIPAM-co-AA) microbeads and show that liposome fusion does not occur under such conditions, that the liposomes remain intact and impermeable when so bound, and that they can function as slow release vehicles for entrapped aqueous species.