Flavonoids are widely distributed in mulberry leaves and have been
recognized for their beneficial physiological effects on the human
health. Here, we analyzed variations in 44 flavonoid compounds among
91 mulberry resources. Metabolic profiling revealed that O-rhamnosylated flavonols and malonylated flavonol glycosides, including
rutin and quercetin 3-O-(6″-O-malonylglucoside) (Q3MG), were absent from Morus
notabilis and multiple mulberry (Morus
alba L.) resources. Transcriptome and phylogenetic
analyses of flavonoid-related UDP-glycosyltransferases (UGTs) suggested
that the flavonol 3-O-glucoside-O-rhamnosyltransferase (FGRT) KT324624 is a key enzyme involved in
rutin synthesis. A recombinant FGRT protein was able to convert kaempferol/quercetin
3-O-glucoside to kaempferol 3-O-rutinoside
(K3G6″Rha) and rutin. The recombinant FGRT was able to use
3-O-glucosylated flavonols but not flavonoid aglycones
or 7-O-glycosylated flavonoids as substrates. The
enzyme preferentially used UDP-rhamnose as the sugar donor, indicating
that it was a flavonol 3-O-glucoside: 6″-O-rhamnosyltransferase. This study provided insights into
the biosynthesis of rutin in mulberry.
Three-dimensional (3D) collective cell migration in a collagen-based extracellular matrix (ECM) is among one of the most significant topics in developmental biology, cancer progression, tissue regeneration, and immune response. Recent studies have suggested that collagen-fiber mediated force transmission in cellularized ECM plays an important role in stress homeostasis and regulation of collective cellular behaviors. Motivated by the recent in vitro observation that oriented collagen can significantly enhance the penetration of migrating breast cancer cells into dense Matrigel which mimics the intravasation process in vivo [Han et al. Proc. Natl. Acad. Sci. USA 113, 11208 (2016)PNASA60027-842410.1073/pnas.1610347113], we devise a procedure for generating realizations of highly heterogeneous 3D collagen networks with prescribed microstructural statistics via stochastic optimization. Specifically, a collagen network is represented via the graph (node-bond) model and the microstructural statistics considered include the cross-link (node) density, valence distribution, fiber (bond) length distribution, as well as fiber orientation distribution. An optimization problem is formulated in which the objective function is defined as the squared difference between a set of target microstructural statistics and the corresponding statistics for the simulated network. Simulated annealing is employed to solve the optimization problem by evolving an initial network via random perturbations to generate realizations of homogeneous networks with randomly oriented fibers, homogeneous networks with aligned fibers, heterogeneous networks with a continuous variation of fiber orientation along a prescribed direction, as well as a binary system containing a collagen region with aligned fibers and a dense Matrigel region with randomly oriented fibers. The generation and propagation of active forces in the simulated networks due to polarized contraction of an embedded ellipsoidal cell and a small group of cells are analyzed by considering a nonlinear fiber model incorporating strain hardening upon large stretching and buckling upon compression. Our analysis shows that oriented fibers can significantly enhance long-range force transmission in the network. Moreover, in the oriented-collagen-Matrigel system, the forces generated by a polarized cell in collagen can penetrate deeply into the Matrigel region. The stressed Matrigel fibers could provide contact guidance for the migrating cell cells, and thus enhance their penetration into Matrigel. This suggests a possible mechanism for the observed enhanced intravasation by oriented collagen.
Introduction
Adolescence is a critical period for physical and mental development. The effect of early life stress on mood disorders has been intensively studied in adults using rodent models, but it has been less studied in adolescents. The present study aimed to examine the effect of early life stress on anxiety‐related and depression‐like behaviors in adolescent C57BL/6 mice and the sex difference.
Methods
C57BL/6 mice of both sexes were used, and early life stressors included maternal separation (MS, P2‐12, 4 hr per day), restraint stress (RS, P33 to 39, 4 hr per day), and their combination (MRS). Open field test, elevated plus maze, and forced swimming test were performed at different time points during adolescence and adulthood.
Results
It was found that MS did not affect the anxiety‐related behaviors of both males and females tested on P30‐31 and P41‐42. RS decreased the anxiety level in adolescent males but did not affect it in the females. MS, RS, and MRS all significantly increased the depression‐like behavior in adolescent males, but only MRS increased the depression‐like behavior in adolescent females. All effects on adolescent males and females did not persist into adulthood.
Conclusion
The present results showed that early life stress affected anxiety‐related and depression‐like behavior in adolescent mice in manners depending on the nature of stress, the developmental period, and sex.
Wearable devices integrated with various electronic modules, biological sensors, and chemical sensors have drawn large public attention. Due to their inherent advantages of superior stretchability, elaborate microstructure, high integration of multiple functions, and low cost, microfluidics are an excellent candidate and have already been widely used in wearable devices. Well‐designed microfluidic devices can realize excellent multiple functions in wearable devices, including sample collecting, handling and storage, sample analysis, signal converting and amplification, mechanic sensing, and power supplying. Moreover, the microfluidic wearable devices with further integration of wireless modules have exhibited potential applications in healthcare monitoring, clinical assessment, and human and intelligent device interaction. This review focuses on the latest advances on multifunctional wearable devices based on microfluidics, primarily including general functions and designs of microfluidic wearable devices, and their specific applications in physiological signal monitoring, clinical diagnosis and therapeutics, and healthcare.
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