Charge distribution and helicity tune the binding of septin's amphipathic helix domain to membranes Wednesday, April 2, 2025 Amphipathic helices (AHs) are secondary structures that can facilitate binding of proteins to the membrane by folding into a helix with hydrophobic and hydrophilic faces that interact with the same surfaces in the lipid membrane. Septins are cytoskeletal proteins that preferentially bind to domains of micron-scale curvature on the cell membrane. Studies have shown that AH domains in septin are essential for curvature sensing. We present the first computational study of septin AH interactions with lipid bilayers. Read more
Mechanical adaptivity of red blood cell flickering to extrinsic membrane stiffening by the solid-like biosurfactant β-Aescin Tuesday, April 1, 2025 β-Aescin is a natural additive employed for treatments of vascular insufficiency, hence its impact in red blood cell (RBC)’s adaptivity has been conjectured. Here, we report a study about the mechanical impact of the membrane stiffener aescin on the flickering motions of live RBCs maintained at the homeostatic status. An active flickering, or nonequilibrium fluctuation dynamics has been revealed by mapping flickering motions in single RBCs treated or not with aescin. Experiments show that active RBC flickers adapt mechanically to β-escin, unlike the passive thermal fluctuations observed in lipid bilayers without an active skeleton. Read more
Single Molecule Measurements of Double-Stranded DNA Condensation Monday, March 31, 2025 Electrostatically driven double stranded (ds)DNA condensation is critical in regulating many biological processes, including bacteriophage and virus replication and the packaging of chromosomal DNA in sperm heads. Here we review single-molecule (SM) measurements of dsDNA condensed by cationic proteins, polypeptides, and small multivalent cations. Optical tweezers (OT) measurements of dsDNA collapsed by cationic condensing agents reveal a critical condensing force unique to each condensing agent that is tunable with condensing agent concentration and ionic strength. Read more
Distinct roles of protrusions and collagen deformation in collective invasion of cancer cell types Monday, March 31, 2025 The breast tumor microenvironment is composed of heterogeneous cell populations, including normal epithelial cells, cancer-associated fibroblasts, and tumor cells that lead collective cell invasion. Both leader tumor cells and CAFs are known to play important roles in tumor invasion across the collagen-rich stromal boundary. However, their individual abilities to utilize their cell-intrinsic protrusions and perform force-based collagen remodeling to collectively invade remain unclear. To compare collective invasion phenotypes of leader-like tumor cells and CAFs, we embedded spheroids composed of 4T1 tumor cells or mouse tumor-derived CAF cell lines within 3D collagen gels and analyzed their invasion and collagen deformation. Read more
Predicted Functional Consequences of WNT Ligand Mutations in Colorectal Cancer Sunday, March 30, 2025 Mutations to WNT ligands in cancer are poorly understood. WNT ligands are a family of secreted proteins that trigger the activation of the WNT pathway with essential roles in cell development and carcinogenesis, particularly of the colorectal tract. Whilst the structure of WNT ligands has been elucidated, little is known about how mutations in these proteins affect colorectal cancer. Here we show that mutations in WNT ligands found in colorectal cancer show regional specificity and selectivity for particular conserved sequences. Read more
Accuracy of distance distributions and dynamics from single-molecule FRET Sunday, March 30, 2025 Single-molecule spectroscopy combined with Förster resonance energy transfer (FRET) is widely used to quantify distance dynamics and distributions in biomolecules. Most commonly, measurements are interpreted using simple analytical relations between experimental observables and the underlying distance distributions. However, these relations make simplifying assumptions, such as a separation of timescales between inter-dye distance dynamics, fluorescence lifetimes, and dye reorientation, the validity of which is notoriously difficult to assess from experimental data alone. Read more
A closed-loop system for millisecond readout and control of membrane tension Sunday, March 30, 2025 Statement of Significance: We describe a novel system that can read out and control tension of a membrane patch in real time. It allows measuring tension-response relationships of force-gated ion channels without the need for hands-on data analysis, thereby accelerating data collection. We envision that the system can be alternatively used to read out and control membrane curvature, thereby additionally enabling the study of how protein function is affected by membrane geometry. Read more
Perspectives: Comparison of Deep Learning Segmentation Models on Biophysical and Biomedical Data Saturday, March 29, 2025 Deep learning based approaches are now widely used across biophysics to help automate a variety of tasks including image segmentation, feature selection, and deconvolution. However, the presence of multiple competing deep learning architectures, each with its own advantages and disadvantages, makes it challenging to select an architecture best suited for a specific application. As such, we present a comprehensive comparison of common models. Here, we focus on the task of segmentation assuming typical (often small) training dataset sizes available from biophysics experiments and compare the following four commonly used architectures: convolutional neural networks, U-Nets, vision transformers, and vision state space models. Read more
A Discard-and-Restart MD algorithm for the sampling of protein intermediate states Friday, March 28, 2025 We introduce a Discard-and-Restart molecular dynamics (MD) algorithm tailored for the sampling of realistic protein intermediate states. It aids computational structure-based drug discovery by reducing the simulation times to compute a "quick sketch" of folding pathways by up to 2000x. The algorithm iteratively performs short MD simulations and measures their proximity to a target state via a collective variable (CV) loss, which can be defined in a flexible fashion, locally or globally. Using the loss, if the trajectory proceeds toward the target, the MD simulation continues. Read more
Agent-based model of the human colon to investigate mechanisms of pathogen colonization resistance Friday, March 28, 2025 Recent global burden of disease studies have shown that bacterial infections are responsible for over 13 million deaths worldwide, or one in every eight deaths, each year. Enteric diarrheal infections, in particular, pose a significant challenge and strain on healthcare systems as many are difficult to address pharmaceutically, and thus, rely primarily on the patient’s own immune system and gut microbiome to fight the infection. Nonetheless, the specific mechanisms behind gut microbiome colonization resistance of enteric pathogens are not well-defined and microbiome diversity is difficult to represent and study experimentally. Read more
Flow Sensitive Ion Channels in Vascular Endothelial Cells: Mechanisms of Activation and Roles in Mechanotransduction Friday, March 28, 2025 The purpose of this review is to evaluate the current knowledge about the mechanisms by which mechanosensitive ion channels are activated by fluid shear stress in endothelial cells. We focus on three classes of endothelial ion channels that are most well studied for their sensitivity to flow and roles in mechanotransduction: inwardly-rectifying K+ channels, Piezo channels and TRPV channels. We also discuss the mechanisms by which these channels initiate and contribute to mechanosensitive signaling pathways. Read more
Are cell length and volume interchangeable in cell cycle analysis? Thursday, March 27, 2025 SIGNIFICANCE: Cell cycle studies regularly use correlations between cell lengths at various cell cycle checkpoints to elucidate the underlying mechanisms. It is unclear whether length is a good proxy for cell volume. Indeed, studies in fission yeast showed that cell width fluctuations can influence the measured correlations, and make length and volume non-interchangeable. Using modeling and data analysis of Escherichia coli experimental data, we find that cell width fluctuations have negligible impact on the correlation structure of cell cycle variables. This implies that for bacteria such as E. coli, length and volume can often be used interchangeably. Our analysis suggests cell width is tightly regulated in E. coli, to an accuracy of ≈ 4% or 10 nm. Read more