Mechanogeneration of Acid from Oxime Sulfonates

The generation of acid under mechanical force is potentially useful for initiating proton-catalyzed changes in polymeric materials. Here we demonstrate that oxime sulfonatesknown photoacid generatorsare also acid generators when activated mechanically. NMR analysis of products suggests that the ultrasound-induced mechanochemical scission of the oxime sulfonate mechanophore also generates a ketone functional moiety, in addition to acid. Both acid and ketone moieties are useful for developing stress-responsive polymeric materials for autonomous self-healing applications

Mechanogeneration of Acid from Oxime Sulfonates

The generation of acid under mechanical force is potentially useful for initiating proton-catalyzed changes in polymeric materials. Here we demonstrate that oxime sulfonatesknown photoacid generatorsare also acid generators when activated mechanically. NMR analysis of products suggests that the ultrasound-induced mechanochemical scission of the oxime sulfonate mechanophore also generates a ketone functional moiety, in addition to acid. Both acid and ketone moieties are useful for developing stress-responsive polymeric materials for autonomous self-healing applications

The complete mitochondrial genome of <i>Allium fistulosum</i> L. (Amaryllidaceae)

Allium fistulosum L. (Linnaeus, Carolus, 1753) is an aromatic vegetable with health benefits and medicinal value. In this study, the complete mitochondrial genome of A. fistulosum was determined. Circular mitochondrial DNA (mtDNA) was 382,053 bp in size, encoded 44 genes, and contained 26 protein-coding genes (PCGs), 14 tRNAs, and four rRNAs. Phylogenetic analysis of amino acid sequences of the 26 PCGs revealed that the closest relationship was between A. fistulosum and Allium cepa. The high-quality mitochondrial genomic sequences of A. fistulosum presented in this study will serve as a useful resource for a range of genetic, functional, evolutionary, and comparative genomic studies on this species of the Amaryllidaceae family.</p

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The complete mitochondrial genome of Allium fistulosum L.</p

Synthesis and Evaluation of Three Azide-Modified Disaccharide Oxazolines as Enzyme Substrates for Single-Step Fc Glycan-Mediated Antibody-Drug Conjugation

Antibody-drug conjugates (ADCs) hold great promise for targeted cancer cell killing. Site-specific antibody-drug conjugation is highly desirable for synthesizing homogeneous ADCs with optimal safety profiles and high efficacy. We have recently reported that azide-functionalized disaccharide oxazolines of the Manβ1,4GlcNAc core were an efficient substrate of wild-type endoglycosidase Endo-S2 for Fc glycan remodeling and conjugation. In this paper, we report the synthesis and evaluation of new disaccharide oxazolines as enzyme substrates for examining the scope of the site-specific conjugation. Thus, azide-functionalized disaccharide oxazolines derived from Manβ1,4GlcNAc, Glcβ1,4GlcNAc, and Galβ1,4GlcNAc (LacNAc) were synthesized. Enzymatic evaluation revealed that wild-type Endo-S2 demonstrated highly relaxed substrate specificity and could accommodate all the three types of disaccharide derivatives for transglycosylation to provide site-specific azide-tagged antibodies, which were readily clicked with a payload to generate homogeneous ADCs. Moreover, we also found that Endo-S2 was able to accommodate drug-preloaded minimal disaccharide oxazolines as donor substrates for efficient glycan transfer, enabling a single-step and site-specific antibody-drug conjugation without the need of an antibody click reaction. The ability of Endo-S2 to accommodate simpler and more easily synthesized disaccharide oxazoline derivatives for Fc glycan remodeling further expanded the scope of this bioconjugation method for constructing homogeneous antibody-drug conjugates in a single-step manner. Finally, cell-based assays indicated that the synthetic homogeneous ADCs demonstrated potent targeted cancer cell killing

Soil enzyme activities, tomato yields and quality.

(XLSX)</p

Topology structure of stealing complex network in simulation experiment domain.

Topology structure of stealing complex network in simulation experiment domain.</p

Soil bacterial diversity indices of different planting patterns.

Soil bacterial diversity indices of different planting patterns.</p

Overall flow chart of monitoring node algorithm.

Tracking and detection have brought great challenges to network security. Therefore, this paper proposes a monitoring method of stealthy complex network attacks considering security situation awareness. By constructing a tracking model of invisible complex network attacks, public monitoring nodes are selected for monitoring. The cost of a single monitoring node is calculated by the algorithm, and the monitoring node is determined by the monitoring node algorithm, so as to reduce the resource occupancy rate of the monitoring node and improve the monitoring accuracy. The simulation results show that this method is stable in the range of 1000 to 4000 nodes, and can effectively monitor the complex network attacks of stealing secrets.</div

Curve of the abundance distribution for three samples.

The horizontal axis shows the relative abundance of OTU in descending order, while the vertical axis shows the proportion of relative abundance of OTU. TY1, Tomato continuous cropping; TY2, Eggplant-tomato rotation; TY3, Arrowhead-tomato rotation.</p