Pseudohexagonal Nb2O5 Anodes for Fast-Charging Potassium-Ion Batteries.

High-rate batteries will play a vital role in future energy storage systems, yet while good progress is being made in the development of high-rate lithium-ion batteries, there is less progress with post-lithium-ion chemistry. In this study, we demonstrate that pseudohexagonal Nb2O5(TT-Nb2O5) can offer a high specific capacity (179 mAh g-1 ∼ 0.3C), good lifetime, and an excellent rate performance (72 mAh g-1 at ∼15C) in potassium-ion batteries (KIBs), when it is composited with a highly conductive carbon framework; this is the first reported investigation of TT-Nb2O5 for KIBs. Specifically, multiwalled carbon nanotubes are strongly tethered to Nb2O5 via glucose-derived carbon (Nb2O5@CNT) by a one-step hydrothermal method, which results in highly conductive and porous needle-like structures. This work therefore offers a route for the scalable production of a viable KIB anode material and hence improves the feasibility of fast-charging KIBs for future applications.

Robust Biomass-Derived Carbon Frameworks as High-Performance Anodes in Potassium-Ion Batteries.

Potassium-ion batteries (PIBs) have become one of the promising candidates for electrochemical energy storage that can provide low-cost and high-performance advantages. The poor cyclability and rate capability of PIBs are due to the intensive structural change of electrode materials during battery operation. Carbon-based materials as anodes have been successfully commercialized in lithium- and sodium-ion batteries but is still struggling in potassium-ion battery field. This work conducts structural engineering strategy to induce anionic defects within the carbon structures to boost the kinetics of PIBs anodes. The carbon framework provides a strong and stable structure to accommodate the volume variation of materials during cycling, and the further phosphorus doping modification is shown to enhance the rate capability. This is found due to the change of the pore size distribution, electronic structures, and hence charge storage mechanism. The optimized electrode in this work shows a high capacity of 175 mAh g-1 at a current density of 0.2 A g-1 and the enhancement of rate performance as the PIB anode (60% capacity retention with the current density increase of 50 times). This work, therefore provides a rational design for guiding future research on carbon-based anodes for PIBs.

In Vitro Nanobody Library Construction by Using Gene Designated-Region Pan-Editing Technology.

Camelid single-domain antibody fragments (nanobodies) are an emerging force in therapeutic biopharmaceuticals and clinical diagnostic reagents in recent years. Nearly all nanobodies available to date have been obtained by animal immunization, a bottleneck restricting the large-scale application of nanobodies. In this study, we developed three kinds of gene designated-region pan-editing (GDP) technologies to introduce multiple mutations in complementarity-determining regions (CDRs) of nanobodies in vitro. Including the integration of G-quadruplex fragments in CDRs, which induces the spontaneous multiple mutations in CDRs; however, these mutant sequences are highly similar, resulting in a lack of sequences diversity in the CDRs. We also used CDR-targeting traditional gRNA-guided base-editors, which effectively diversify the CDRs. And most importantly, we developed the self-assembling gRNAs, which are generated by reprogrammed tracrRNA hijacking of endogenous mRNAs as crRNAs. Using base-editors guided by self-assembling gRNAs, we can realize the iteratively diversify the CDRs. And we believe the last GDP technology is highly promising in immunization-free nanobody library construction, and the full development of this novel nanobody discovery platform can realize the synthetic evolution of nanobodies in vitro.

Chimeric antigen receptor-modified macrophages trigger systemic anti-tumour immunity.

Preliminary results and emerging data have shown that lipid droplet high (LDhi ) immunosuppressive cells accumulate in tumour tissues. By tracking and phenotypic profiling of LDhi cells, we find that LDhi CD19+ , LDhi CD11b+ , and LDhi Ly6G+ immune cell populations appear in the spleen, thymus, and tumour tissues in a syngeneic tumour model. Using a contact-dependent reporter system, we discover a LDhi CCR7hi immunosuppressive cell population that migrates from tumour tissues to the spleen and thymus. Hence, we engineered a family of chimeric antigen receptor-modified macrophages (CAR-Ms) that direct macrophages to CCR7-positive cells and show that the cytosolic domain from Mer receptor tyrosine kinase (MerTK) triggers tumour cell cytotoxicity by the CAR-Ms. In vivo, CCR7-targeted CAR-Ms suppressed tumour growth and prolonged survival by preventing metastasis and by inducing systemic anti-tumour immunity through retarding the migration of LDhi CCR7hi immunosuppressive cells from tumour tissues to distal immune organs, indicating an important role for CCR7 in tumour cell-induced immune tolerance. © 2020 The Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.

Genome-wide identification and characterization of nonspecific lipid transfer protein (nsLTP) genes in Arachis duranensis.

Nonspecific lipid transfer proteins (nsLTPs) play vital roles in lipid metabolism, cell apoptosis and biotic and abiotic stresses in plants. However, the distribution of nsLTPs in Arachis duranensis has not been fully characterized. In this study, we identified 64 nsLTP genes in A. duranensis (designated AdLTPs), which were classified into six subfamilies and randomly distributed along nine chromosomes. Tandem and segmental duplication events were detected in the evolution of AdLTPs. The Ks and ω values differed significantly between Types 1 and D subfamilies, and eight AdLTPs were under positive selection. The expression levels of AdLTPs were changed after salinity, PEG, low-temperature and ABA treatments. Three AdLTPs were associated with resistance to nematode infection, and DOF and WRI1 transcription factors may regulate the AdLTP response to nematode infection. Our results may provide valuable genomic information for the breeding of peanut cultivars that are resistant to biotic and abiotic stresses.