Biological ion channels precisely control the flow of ions across membranes in response to a range of physical and chemical stimuli. With their ability of transporting ions in a highly selective manner and of integrating regulatory cues, they are a source of inspiration for the construction of solid-state nanopores as sensors or switches for practical applications. Here, we summarize recent advancements in understanding the mechanisms of ion permeation and gating in channel proteins with a focus on the elementary steps of ion transport through the pore and on non-canonical modes of intramolecular communication between peripheral sensory domains and the central channel pore
A novel conceptual model is introduced in which ion permeation is coupled to the protein wall vibrat...
Synthetic nanopores and mesoscopic protein channels have common traits like the importance of electr...
The field of ion channels has entered into a rapid phase of development in the last few years, partl...
Ion channels are gated, i.e. they can switch conformation between a closed and an open state. Molecu...
Ion channels are biological nanotubes that are formed by membrane proteins. Because ion channels reg...
Ion transport across cell membranes is essential to cell communication and signaling. Passive ion tr...
Ion channels are gated, i.e. they can switch conformation between a closed and an open state. Molecu...
Membrane ion channels contain integral pores that precisely select their permeant ions. This selecti...
AbstractIon channels are gated, i.e. they can switch conformation between a closed and an open state...
Ion channels are hollow proteins that have evolved to exhibit discrimination between charged solutes...
AbstractBiological ion channels are nanoscale transmembrane pores. When water and ions are enclosed ...
<p>Ion channels such as the nicotinic acetylcholine receptor (nAChR) fulfil essential roles in fast ...
K+-channels are membrane proteins that regulate the selective conduction of potassium ions across ce...
The cells that make up living organisms are enclosed by hydrophobic membranes that restrict movement...
Ion channels are formed by specific proteins embedded in the cell membrane and provide pathways for ...
A novel conceptual model is introduced in which ion permeation is coupled to the protein wall vibrat...
Synthetic nanopores and mesoscopic protein channels have common traits like the importance of electr...
The field of ion channels has entered into a rapid phase of development in the last few years, partl...
Ion channels are gated, i.e. they can switch conformation between a closed and an open state. Molecu...
Ion channels are biological nanotubes that are formed by membrane proteins. Because ion channels reg...
Ion transport across cell membranes is essential to cell communication and signaling. Passive ion tr...
Ion channels are gated, i.e. they can switch conformation between a closed and an open state. Molecu...
Membrane ion channels contain integral pores that precisely select their permeant ions. This selecti...
AbstractIon channels are gated, i.e. they can switch conformation between a closed and an open state...
Ion channels are hollow proteins that have evolved to exhibit discrimination between charged solutes...
AbstractBiological ion channels are nanoscale transmembrane pores. When water and ions are enclosed ...
<p>Ion channels such as the nicotinic acetylcholine receptor (nAChR) fulfil essential roles in fast ...
K+-channels are membrane proteins that regulate the selective conduction of potassium ions across ce...
The cells that make up living organisms are enclosed by hydrophobic membranes that restrict movement...
Ion channels are formed by specific proteins embedded in the cell membrane and provide pathways for ...
A novel conceptual model is introduced in which ion permeation is coupled to the protein wall vibrat...
Synthetic nanopores and mesoscopic protein channels have common traits like the importance of electr...
The field of ion channels has entered into a rapid phase of development in the last few years, partl...