Litcius/Paper detail

Paralemmin-1 controls the nanoarchitecture of the neuronal submembrane cytoskeleton

Victor Macarrón‐Palacios, Jasmine Hubrich, Maria Augusta do Rego Barros Fernandes Lima, Nicole G. Metzendorf, Simon Kneilmann, Marleen Trapp, Claudio Acuna, Annarita Patrizi, Elisa D’Este, Manfred W. Kilimann

2025Science Advances10 citationsDOIOpen Access PDF

Abstract

The submembrane cytoskeleton of neurons displays a highly ordered 190-nanometer periodic actin-spectrin lattice, the membrane-associated periodic skeleton (MPS). It is involved in mechanical resilience, signaling, and action potential transmission. Here, we identify paralemmin-1 (Palm1) as a component and regulator of the MPS. Palm1 binds to the amino-terminal region of βII-spectrin, and MINFLUX microscopy localizes it in close proximity (<20 nanometers) to the actin-capping protein and MPS component adducin. Combining overexpression, knockout, and rescue experiments, we observe that the expression level of Palm1 controls the degree of periodicity of the MPS and also affects the electrophysiological properties of neurons. A single amino acid mutation (W54A) in Palm1 abolishes the MPS binding and remodeling activities of Palm1. Our findings identify Palm1 as a protein specifically dedicated to organizing the MPS and will advance the understanding of the assembly and plasticity of the actin-spectrin submembrane skeleton in general.

Topics & Concepts

SpectrinCell biologyCytoskeletonActinRegulatorActin cytoskeletonSubcellular localizationAnkyrinSignal transducing adaptor proteinChemistryBiologyBiophysicsSignal transductionBiochemistryCellCytoplasmGeneCellular Mechanics and InteractionsRNA Research and SplicingAdvanced Fluorescence Microscopy Techniques
Paralemmin-1 controls the nanoarchitecture of the neuronal submembrane cytoskeleton | Litcius