Your search keyword '"Bieck M"' showing total 2 results

1. Claudin-4 polymerizes after a small extracellular claudin-3-like substitution.

Author

van der Veen RE, Piontek J, Bieck M, Saiti A, Gonschior H, and Lehmann M

Subjects

Humans, Animals, Amino Acid Sequence, Amino Acid Substitution, Protein Multimerization, Claudin-4 metabolism, Claudin-4 genetics, Tight Junctions metabolism, Claudin-3 metabolism, Claudin-3 genetics, Claudin-3 chemistry, Molecular Dynamics Simulation

Abstract

Tight junctions play a pivotal role in the functional integrity of the human body by forming barriers that compartmentalize tissues and protect the body from external threats. Essential components of tight junctions are the transmembrane claudin proteins, which can polymerize into tight junction strands and meshworks. This study delves into the structural determinants of claudin polymerization, using the close homology yet strong difference in polymerization capacity between claudin-3 and claudin-4. Through a combination of sequence alignment and structural modeling, critical residues in the second extracellular segment are pinpointed. Molecular dynamics simulations provide insights into the interactions of and the conformational changes induced by the identified extracellular segment 2 residues. Live-stimulated emission depletion imaging demonstrates that introduction of these residues from claudin-3 into claudin-4 significantly enhances polymerization in nonepithelial cells. In tight junction-deficient epithelial cells, mutated claudin-4 not only influences tight junction morphology but also partially restores barrier function. Understanding the structural basis of claudin polymerization is crucial, as it offers insights into the dynamic nature of tight junctions. This knowledge could be applied to targeted therapeutic interventions, offer insight to repair or prevent barrier defects associated with pathological conditions, or introduce temporary barrier openings during drug delivery., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

2. A one-step protocol to generate impermeable fluorescent HaloTag substrates for in situ live cell application and super-resolution imaging.

Author

Roßmann K, Sun S, Olesen CH, Kowald M, Tapp E, Pabst U, Bieck M, Birke R, Shields BC, Jeong P, Hong J, Tadross MR, Levitz J, Lehmann M, Lipstein N, and Broichhagen J

Abstract

Communication between cells is largely orchestrated by proteins on the cell surface, which allow information transfer across the cell membrane. Super-resolution and single-molecule visualization of these proteins can be achieved by genetically grafting HTP (HaloTag Protein) into the protein of interest followed by brief incubation of cells with a dye-HTL (dye-linked HaloTag Ligand). This approach allows for use of cutting-edge fluorophores optimized for specific optical techniques or a cell-impermeable dye-HTL to selectively label surface proteins without labeling intracellular copies. However, these two goals often conflict, as many high-performing dyes exhibit membrane permeability. Traditional methods to eliminate cell permeability face synthetic bottlenecks and risk altering photophysical properties. Here we report that dye-HTL reagents can be made cell-impermeable by inserting a charged sulfonate directly into the HTL, leaving the dye moiety unperturbed. This simple, one-step method requires no purification and is compatible with both the original HTL and second-generation HTL.2, the latter offering accelerated labeling. We validate such compounds, termed dye-SHTL ('dye shuttle') conjugates, in live cells via widefield microscopy, demonstrating exclusive membrane staining of extracellular HTP fusion proteins. In transduced primary hippocampal neurons, we label mGluR2, a neuromodulatory G protein-coupled receptor (GPCR), with dyes optimized for stimulated emission by depletion (STED) super-resolution microscopy, allowing unprecedented accuracy in distinguishing surface and receptors from those in internal compartments of the presynaptic terminal, important in neural communication. This approach offers broad utility for surface-specific protein labelling., Competing Interests: COMPETING INTERESTS NL is a member of the scientific advisory board of Trace Neuroscience. MRT and BCS are on patent applications describing HTL.2. All other authors declare no competing interests.

Published

2024