RESUMO
Talins are cytoskeletal linker proteins that consist of an N-terminal head domain, a flexible neck region and a C-terminal rod domain made of 13 helical bundles. The head domain binds integrin ß-subunit cytoplasmic tails, which triggers integrin conformational activation to increase affinity for extracellular matrix proteins. The rod domain links to actin filaments inside the cell to transmit mechanical loads and serves as a mechanosensitive signalling hub for the recruitment of many other proteins. The α-helical bundles function as force-dependent switches - proteins that interact with folded bundles are displaced when force induces unfolding, exposing previously cryptic binding sites for other ligands. This leads to the notion of a talin code. In this Cell Science at a Glance article and the accompanying poster, we propose that the multiple switches within the talin rod function to process and store time- and force-dependent mechanical and chemical information.
Assuntos
Mecanotransdução Celular , Talina , Sítios de Ligação , Integrinas/metabolismo , Ligação Proteica , Transdução de Sinais , Talina/genética , Talina/metabolismoRESUMO
One of the major unsolved mysteries of biological science concerns the question of where and in what form information is stored in the brain. I propose that memory is stored in the brain in a mechanically encoded binary format written into the conformations of proteins found in the cell-extracellular matrix (ECM) adhesions that organise each and every synapse. The MeshCODE framework outlined here represents a unifying theory of data storage in animals, providing read-write storage of both dynamic and persistent information in a binary format. Mechanosensitive proteins that contain force-dependent switches can store information persistently, which can be written or updated using small changes in mechanical force. These mechanosensitive proteins, such as talin, scaffold each synapse, creating a meshwork of switches that together form a code, the so-called MeshCODE. Large signalling complexes assemble on these scaffolds as a function of the switch patterns and these complexes would both stabilise the patterns and coordinate synaptic regulators to dynamically tune synaptic activity. Synaptic transmission and action potential spike trains would operate the cytoskeletal machinery to write and update the synaptic MeshCODEs, thereby propagating this coding throughout the organism. Based on established biophysical principles, such a mechanical basis for memory would provide a physical location for data storage in the brain, with the binary patterns, encoded in the information-storing mechanosensitive molecules in the synaptic scaffolds, and the complexes that form on them, representing the physical location of engrams. Furthermore, the conversion and storage of sensory and temporal inputs into a binary format would constitute an addressable read-write memory system, supporting the view of the mind as an organic supercomputer.
RESUMO
Memory loss induced by aging and hypoxia is very common, so exploring the mechanism of memory production, storage and retrieval is of great significance to daily life and clinical work. The storage and retrieval of memory is probably similar to the computer. We summarized the research progress of MeshCODE theory, the mechanical basis of memory. Memory loss in certain diseases (such as Alzheimer's disease) or pathological conditions (such as aging, lack of oxygen) may be associated with abnormal folding of talin, a mechanosensitive protein. It can dynamically regulate synaptic activity by changing the state of the domain, storing or updating information about small changes in mechanical forces in binary form, and initiating chemical processes such as ligand redistribution in neurons, so that memory is stored in the brain in a binary format, known as the MeshCODE theory.