Computational modeling of a dynamin-constricted membrane neck can rank proposed shape changes of the helical scaffold in terms of their fission aptitude and elucidate the associated pathways.

A new approach using combination of electron microscopy (EM) and high-speed atomic force microscopy (HS-AFM) clearly demonstrates dynamics of dynamin-amphiphysin complexes during membrane constriction and fission suggesting a novel 'clusterase' model of the dynamin-mediated membrane fission.

Quantitative 3D lattice light sheet microscopy of unperturbed cells combined with electron tomography and acute loss of function experiments reveals how dynamic ESCRT-III/Vps4 assemblies succeed in reverse membrane budding on endosomes.

The BAR protein endophilin spaces out turns of the dynamin helix, blocking its active conformational change and membrane fission.

Membrane potential recordings in awake mice from two genetically defined classes of neocortical inhibitory neurons reveal their distinct patterns of activity and unitary excitatory synaptic inputs, which are differentially modulated by behavior and local network activity.

A single amino acid residue is critical for cardiolipin interaction specificity and nuclear membrane recruitment of a dynamin-related protein.

Local inward plasma membrane deformations caused by actomyosin-dependent contraction trigger the dynamic recruitment of a curvature-sensitive actin-regulatory protein, which represents a receptor-independent auto-regulatory mechanism to control local actin polymerization dynamics at the plasma membrane.

ACCuRET is a flexible new method for measuring the structural dynamics of proteins in solution and membrane proteins in their native environment.

TMEM127 depletion alters membrane dynamics, promoting cell surface accumulation and constitutive activity of growth factor receptors, and ultimately providing a novel paradigm for oncogenesis through aberrant receptor localization and signaling.

The axial organization and dynamics of the HOPS complex at membrane surface are resolved by graphene-induced energy transfer with subnanometer resolution.