Supercapacitors are increasingly in demand among energy storage devices. Due to their abundant porosity and low cost, activated carbons are the most promising electrode materials and have been commercialized in supercapacitors for many years. However, their low packing density leads to an unsatisfactory volumetric performance, which is a big obstacle for their practical use where a high volumetric energy density is necessary. Inspired by the dense structure of irregular pomegranate grains, a simple yet effective approach to pack activated carbons into a compact graphene network with graphene as the “peels” is reported here. The capillary shrinkage of the graphene network sharply reduces the voids between the activated carbon particles through the microcosmic rearrangement while retaining their inner porosity. As a result, the electrode density increases from 0.41 to 0.76 g cm
−3
. When used as additive‐free electrodes for supercapacitors in an ionic liquid electrolyte, this porous yet dense electrode delivers a volumetric capacitance of up to 138 F cm
−3
, achieving high gravimetric and volumetric energy densities of 101 Wh kg
−1
and 77 Wh L
−1
, respectively. Such a graphene‐assisted densification strategy can be extended to the densification of other carbon or noncarbon particles for energy devices requiring a high volumetric performance.
The key aroma-active compounds were identified in basic and characteristic meaty flavour yeast extract pastes, and their characterisation was determined.
Graphene has a unique planar structure, as well as excellent electronic properties, and has attracted a great deal of interest from scientists. Graphene and its derivatives display advantageous characteristics as a biosensing platform due to their high surface area, good biocompatibility and ease of functionalization. Moreover, graphene and its derivatives exhibit excellent optical properties; thus they are considered to be promising and attractive candidates for bioimaging, mainly of cells and tissues. Following an introduction and a discussion of the optical properties of graphene, this review assesses the methods for engineering the functions of graphene and its derivatives. Specific examples are given on the use of graphene and its derivatives in fluorescence bioimaging, surface-enhanced Raman scattering (SERS) imaging, and magnetic resonance imaging (MRI). Finally, the prospects and further developments in this exciting field of graphene-based materials are suggested.
Protein acetylation of histone is an essential post-translational modification (PTM) mechanism in epigenetic gene regulation, and its status is reversibly controlled by histone acetyltransferases (HATs) and histone deacetylases (HDACs). Herein, we have developed a sensitive and label-free time-resolved luminescence (TRL) biosensor for continuous detection of enzymatic activity of HATs and HDACs, respectively, based on acetylation-mediated peptide/DNA interaction and Tb(3+)/DNA luminescent probes. Using guanine (G)-rich DNA-sensitized Tb(3+) luminescence as the output signal, the polycationic substrate peptides interact with DNA with high affinity and subsequently replace Tb(3+), eliminating the luminescent signal. HAT-catalyzed acetylation remarkably reduces the positive charge of the peptides and diminishes the peptide/DNA interaction, resulting in the signal on detection via recovery of DNA-sensitized Tb(3+) luminescence. With this TRL sensor, HAT (p300) can be sensitively detected with a wide linear range from 0.2 to 100 nM and a low detection limit of 0.05 nM. The proposed sensor was further used to continuously monitor the HAT activity in real time. Additionally, the TRL biosensor was successfully applied to evaluating HAT inhibition by two specific inhibitors, anacardic acid and C464, and satisfactory Z'-factors above 0.73 were obtained. Moreover, this sensor is feasible to continuously monitor the HDAC (Sirt1)-catalyzed deacetylation with a linear range from 0.5 to 500 nM and a detection limit of 0.5 nM. The proposed sensor is a convenient, sensitive, and mix-and-read assay, presenting a promising platform for protein acetylation-targeted epigenetic research and drug discovery.
Bioimaging probes for accurately monitoring apoptosis process have extensive significance for cell biological studies and clinical investigations. Herein, novel multifunctional peptide-tailored gold nanoclusters (AuNCs) have been developed for real-time imaging of caspase-indicated cell apoptosis. The AuNCs nanoprobe was facilely prepared by a one-step peptide-mediated biomineralization with the dye (TRAMA)-tagged peptides specific to caspase 3 as both template agents and the signal switch. Unlike conventional FRET-based fluorescent probes of caspase activity, these nanoprobes relied on the unique quenching effect of AuNCs through the nanosurface energy transfer (NSET) from dye to AuNCs. Intracellular caspase 3 activation cleaved the substrate peptide and released the dye from AuNCs, leading to a significant fluorescence lighting-up for sensitive and continuous analysis of caspase 3 activity in live cells, with a high signal-background ratio, wide linear range (32 pM-10 nM), and ultralow detection limit (12 pM). Moreover, this versatile AuNCs nanoprobe can serve as a theranostic platform via codisplaying pro-apoptotic and detecting peptides, which allows in situ activation and real-time monitoring of apoptosis in cancer cells. These results indicate that the AuNCs nanoprobe provides a smart molecular imaging and therapeutic agent targeted to cell apoptosis, which has great potential for apoptosis-related diagnosis and precision chemotherapy.
Protein phosphorylation catalyzed by protein kinases plays a critical role in many intracellular processes, and detecting kinase activity is important in biochemical research and drug discovery. Herein, we developed a novel fluorescent biosensor to detect protein kinase activity based on phosphorylation-mediated assembly of semisynthetic green fluorescent protein (GFP). A chimaera S-peptide composed of the 10th β-strand of GFP (s10) and a kinase substrate peptide was synthesized. Kinase-catalyzed phosphorylation of the S-peptide can protect its s10 part against cleavage by carboxypeptidase Y (CPY). Then, the peptide can bind the truncated GFP (tGFP, GFP without s10) to assemble intact GFP and recover fluorescence. Unphosphorylated S-peptide would be degraded by CPY, and fluorescent protein assembly could not occur. Thus, the kinase-catalyzed phosphorylation can switch on the fluorescence signal. This platform has been successfully applied to detect the activity of cAMP-dependent protein kinase with a low detection limit of 0.50 mU/μL and its inhibition of H-89 with an IC50 value of 23.4 nM. The feasibility of this method has been further demonstrated by assessment of the kinase activity and inhibition in the cell lysate. Moreover, based on the reverse principle, this method was expanded to detect the activity of protein phosphatase 1. Our method, using semisynthetic GFP as a readout, is facile, sensitive, label-free, and highly versatile, thus showing great potential as a promising platform for protein kinase detection and inhibitor screening.
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