Robert Wieduwild scite author profile

SUMMARYThe Gram-negative phytopathogenic bacterium Xanthomonas campestris pv. vesicatoria (Xcv) employs a type III secretion system to translocate effector proteins into plant cells where they modulate host signaling pathways to the pathogen's benefit. The effector protein AvrBs3 acts as a eukaryotic transcription factor and induces the expression of plant genes termed UPA (up-regulated by AvrBs3). Here, we describe 11 new UPA genes from bell pepper that are induced by AvrBs3 early after infection with Xcv. Sequence comparisons revealed the presence of a conserved AvrBs3-responsive element, the UPA box, in all UPA gene promoters analyzed. Analyses of UPA box mutant derivatives confirmed its importance for gene induction by AvrBs3. We show that DNA binding and gene activation were strictly correlated. DNase I footprint studies demonstrated that the UPA box corresponds to the center of the AvrBs3-protected DNA region. Type III delivery of AvrBs3 and mutant derivatives showed that some UPA genes are induced by the AvrBs3 deletion derivative AvrBs3Drep16, which lacks four repeats. We show that AvrBs3Drep16 recognizes a mutated UPA box with two nucleotide exchanges in positions that are not essential for binding and activation by AvrBs3.

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Minimal Peptide Motif for Non-covalent Peptide–Heparin Hydrogels

Wieduwild

Tsurkan

Chwalek

et al. 2013

J. Am. Chem. Soc.

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Reduction of complexity of the extracellular matrix (ECM) to a non-covalent structure with minimal chemically defined components represents an attractive avenue for understanding the biology of the ECM. The resulting system could lead to the design of tailor-made biomaterials that incorporate varying functionalities. Negatively charged glycosaminoglycans are the major components of the ECM. Their interaction with positively charged proteins is important for dynamic three-dimensional scaffold formation and function. We designed and screened minimal peptide motifs whose conjugates with polyethylene glycol interact with heparin to form non-covalent hydrogels. Here we show the structure/function relationship of the (RA) n and (KA) n motifs and determined that both basic residues and the heparin-induced α-helix formation are important for the assembly process. Simple rules allowed us to tune various aspects of the matrix system such as the gelation rates, biodegradability, rheological properties, and biofunctionality. The hydrogels can encapsulate cells and support cell survival.

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Cytocompatible, Injectable, and Electroconductive Soft Adhesives with Hybrid Covalent/Noncovalent Dynamic Network

Patsis

Hauser

et al. 2019

Advanced Science

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Synthetic conductive biopolymers have gained increasing interest in tissue engineering, as they can provide a chemically defined electroconductive and biomimetic microenvironment for cells. In addition to low cytotoxicity and high biocompatibility, injectability and adhesiveness are important for many biomedical applications but have proven to be very challenging. Recent results show that fascinating material properties can be realized with a bioinspired hybrid network, especially through the synergy between irreversible covalent crosslinking and reversible noncovalent self‐assembly. Herein, a polysaccharide‐based conductive hydrogel crosslinked through noncovalent and reversible covalent reactions is reported. The hybrid material exhibits rheological properties associated with dynamic networks such as self‐healing and stress relaxation. Moreover, through fine‐tuning the network dynamics by varying covalent/noncovalent crosslinking content and incorporating electroconductive polymers, the resulting materials exhibit electroconductivity and reliable adhesive strength, at a similar range to that of clinically used fibrin glue. The conductive soft adhesives exhibit high cytocompatibility in 2D/3D cell cultures and can promote myogenic differentiation of myoblast cells. The heparin‐containing electroconductive adhesive shows high biocompatibility in immunocompetent mice, both for topical application and as injectable materials. The materials could have utilities in many biomedical applications, especially in the area of cardiovascular diseases and wound dressing.

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Tethered agonist exposure in intact adhesion/class B2 GPCRs through intrinsic structural flexibility of the GAIN domain

et al. 2021

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In Vivo Examination of an Injectable Hydrogel System Crosslinked by Peptide–Oligosaccharide Interaction in Immunocompetent Nude Mice

Tondera

Wieduwild

Röder

et al. 2017

Adv Funct Materials

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Hydrogels can serve as matrices to mimic natural tissue function and be used for wide‐ranging applications such as tissue regeneration and drug delivery. Injectable hydrogels are particularly favorable because their uses are minimally invasive. However, creating moldable substance for injection often results in compromised function and stability. This study reports an injectable hydrogel system crosslinked by peptide–oligosaccharide noncovalent interaction. The dynamic network shows fast self‐healing, a property essential for injectability. Injected hydrogels in immunocompetent mice and release of encapsulated compound are monitored up to 9 months by magnetic resonance imaging (MRI) and optical imaging. This surprisingly stable hydrogel does not cause adverse inflammatory response, as analyzed by measuring cytokine levels, immunohistochemistry, and MRI. Hydrogel degradation is associated with invasion of macrophages and vascular formation. The facile synthesis, high biocompatibility, and stability of this injectable hydrogel can lead to various experimental and clinical applications in regenerative medicine and drug delivery.

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