Phage-coded lysin is an enzyme that destroys the cell walls of bacteria. Phage lysin could be an alternative to conventional antibiotic therapy against pathogens that are resistant to multiple antibiotics. In this study, a novel staphylococcal phage, GH15, was isolated, and the endogenous lytic enzyme (LysGH15) was expressed and purified. The lysin LysGH15 displayed a broad lytic spectrum; in vitro treatment killed a number of Staphylococcus aureus strains rapidly and completely, including methicillinresistant S. aureus (MRSA). In animal experiments, a single intraperitoneal injection of LysGH15 (50 g) administered 1 h after MRSA injections at double the minimum lethal dose was sufficient to protect mice (P < 0.01). Bacteremia in unprotected mice reached colony counts of about 10 7 CFU/ml within 3.5 h after challenge, whereas the mean colony count in lysin-protected mice was less than 10 4 CFU/ml (and ultimately became undetectable). These results indicate that LysGH15 can kill S. aureus in vitro and can protect mice efficiently from bacteremia in vivo. The phage lysin LysGH15 might be an alternative treatment strategy for infections caused by MRSA.Staphylococcus aureus is a common and dangerous pathogen that causes various infectious diseases, including skin abscesses, wound infections, endocarditis, osteomyelitis, pneumonia, and toxic shock syndrome (2, 23). Treatment of these infections has become ever more difficult due to the emergence of multidrug-resistant strains, especially methicillin-resistant S. aureus (MRSA) (15,25,26,36,37). Vancomycin was effective against MRSA, but certain MRSA strains have already acquired resistance to vancomycin as well (vancomycin-resistant S. aureus [VRSA]), raising serious concerns within the medical community (17,18,37). Therefore, there is an urgent need for novel therapeutic agents directed against this formidable pathogen (2, 9).The phage lysin is encoded by the bacteriophage genome and is synthesized at the end of the phage lytic life cycle to lyse the host cell (30). Lysins belong to the family of mureolytic enzymes that directly destroy peptidoglycans in the bacterial cell wall. Previous studies have suggested that lysins from certain phages were highly efficient in lysing bacteria, especially when applied exogenously (11,14,21,22,29,35). As a potential antibacterial agent, lysins possess several promising features, namely, a distinct mode of action, species or type specificity, and bactericidal activity independent of the antibiotic susceptibility pattern (1). Indeed, there is a low probability that bacteria will develop resistance against lysin (12, 21).Some Staphylococcus phage lysins have been isolated and studied, including LysK, ClyS, MV-L, LysWMY, and ⌽H5; however, only MV-L and ClyS have been studied in in vivo assays (6, 33). In this study, a novel myovirus phage infecting S. aureus was isolated. The lysin derived from this phage, LysGH15, was expressed and refined. The lysin LysGH15 demonstrated a very broad host range and strong lytic activity. We evaluate...
Upconversion emission dynamics have long been believed to be determined by the activator and its interaction with neighboring sensitizers. Herein this assumption is, however, shown to be invalid for nanostructures. We demonstrate that excitation energy migration greatly affects upconversion emission dynamics. “Dopant ions’ spatial separation” nanostructures are designed as model systems and the intimate link between the random nature of energy migration and upconversion emission time behavior is unraveled by theoretical modelling and confirmed spectroscopically. Based on this new fundamental insight, we have successfully realized fine control of upconversion emission time behavior (either rise or decay process) by tuning the energy migration paths in various specifically designed nanostructures. This result is significant for applications of this type of materials in super resolution spectroscopy, high‐density data storage, anti‐counterfeiting, and biological imaging.
Photoswitchable materials are important in broad applications. Recently appeared inorganic photoswitchable upconversion nanoparticles (PUCNPs) become a competitive candidate to surmount the widespread issue of the organic counterparts -photobleaching. However, current PUCNPs follow solely Yb/Nd cosensitizing mode, which results in complex multilayer doping patterns and imperfectness of switching in UV-blue region. In this work, we have adopted a new strategy to construct Nd free PUCNPs-NaErF@NaYF@NaYbF:0.5%Tm@NaYF. These PUCNPs demonstrate the superior property of photoswitching. A prominent UV-blue emission from Tm is turned on upon 980 nm excitation, which can be completely turned off by 800 nm light. The quasi-monochromatic red upconversion emission upon 800 nm excitation-a distinct feature of undoping NaErF upconversion system-endows the PUCNPs with promising image-guided photoinduced "off-on" therapy in biomedicine. As a proof-of-concept we have demonstrated the imaging-guided photodynamic therapy (PDT) of cancer, where 800 nm excitation turns off the UV-blue emission and leaves the emission at 660 nm for imaging. Once the tumor site is targeted, excitation switching to 980 nm results in UV-blue emission and the red emission. The former is used to induce PDT, whereas the latter is to monitor the therapeutic process. Our study implies that this upconversion photoswitching material is suitable for real-time imaging and image-guided therapy under temporal and spatial control.
It is generally accepted that a lanthanide ions based upconversion material follows an activator low doping strategy (normally <3 mol%), because of the restriction of the harmful concentration quenching effect. Here, we demonstrate that this limitation can be broken in nanostructures. Simply by using an inert shell coating strategy, the concentration quenching effect for the activator (Er) could be eliminated and highly efficient upconversion luminescence realized in the activator fully doped nanostructure, e.g. NaErF@NaYF. More importantly, this novel nanostructure achieves some long-cherished desires, such as multiple-band co-excitation (∼800 nm, ∼980 nm and ∼1530 nm) and monochromic red emission. Proof-of-concept experiments are presented of the potential benefit of this structure in solar cells and anti-counterfeiting. This nanostructure offers new possibilities in realizing high upconversion emission and novel functionalities of lanthanide based nanomaterials.
Flaky hexagonal boron nitride particles-reinforced epoxy composites were prepared. The investigation on the thermal, electrical, and mechanical properties of hexagonal boron nitride/epoxy composites indicated that the incorporation of silane coupling agent-treated hexagonal boron nitride into epoxy slightly improved the glass transition temperature and the thermal stability of the composites; the epoxy containing silane treated hexagonal boron nitride exhibited higher thermal conductivity compared to the untreated ones. The dielectric permittivity increased slowly with an increase in hexagonal boron nitride content, as well as with a decrease in frequency. The obtained 50 wt% hexagonal boron nitride–filled epoxy composite had a low dielectric permittivity (less than 5.4) and dielectric loss (less than 0.02) in all frequencies ranging from 10−1 to 107 Hz, a high volume resistivity of 6.3 × 1014 Ω·cm, and a high dielectric strength of 16 kV/mm, together with moderate mechanical properties, which are of great significance for practical electrical materials applications.
The great application potential of triangular silver nanoprisms (TSNPRs, also referred to as triangular silver nanoplates) is hampered by the lack of methods to produce well-defined tips with high monodispersity, with easily removable ligands. In this work, a simple one-step plasmon-mediated method was developed to prepare monodisperse high-quality TSNPRs. In this approach, the sole surface capping agent was the easily removable trisodium citrate. Differing from common strategies using complex polymers, OH(-) ions were used to improve the monodispersity of silver seeds, as well as to control the growth process through inhibiting the oxidation of silver nanoparticles. Using these monodisperse high-quality TSNPRs as building blocks, self-assembled TSNPRs consisting of six-tip based "hot spots" were realized for the first time as demonstrated in a high enhancement (∼10(7)) of surface-enhanced Raman scattering (SERS). From the plasmon band shift versus the refractive index, ultra-high local surface plasmon resonance sensitivity (413 nm RIU(-1) or 1.24 eV RIU(-1), figure of merit (FOM) = 4.59) was reached at ∼630 nm, making these materials promising for chemical/biological sensing applications.
Accurate quantitation of intracellular pH (pHi) is of great importance in revealing the cellular activities and early warning of diseases. A series of fluorescence-based nano-bioprobes composed of different nanoparticles or/and dye pairs have already been developed for pHi sensing. Till now, biological auto-fluorescence background upon UV-Vis excitation and severe photo-bleaching of dyes are the two main factors impeding the accurate quantitative detection of pHi. Herein, we have developed a self-ratiometric luminescence nanoprobe based on förster resonant energy transfer (FRET) for probing pHi, in which pH-sensitive fluorescein isothiocyanate (FITC) and upconversion nanoparticles (UCNPs) were served as energy acceptor and donor, respectively. Under 980 nm excitation, upconversion emission bands at 475 nm and 645 nm of NaYF4:Yb3+, Tm3+ UCNPs were used as pHi response and self-ratiometric reference signal, respectively. This direct quantitative sensing approach has circumvented the traditional software-based subsequent processing of images which may lead to relatively large uncertainty of the results. Due to efficient FRET and fluorescence background free, a highly-sensitive and accurate sensing has been achieved, featured by 3.56 per unit change in pHi value 3.0–7.0 with deviation less than 0.43. This approach shall facilitate the researches in pHi related areas and development of the intracellular drug delivery systems.
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