Posts tagged potassium
Articles and news from the latest research reports.
International research collaboration reveals the mechanism of the sodium-potassium pump
It’s not visible to the naked eye and you can’t feel it, but up to 40 per cent of your body’s energy goes into supplying the microscopic sodium-potassium pump with the energy it needs. The pump is constantly doing its job in every cell of all animals and humans. It works much like a small battery which, among other things, maintains the sodium balance which is crucial to keep muscles and nerves working.
The sodium-potassium pump transports sodium out and potassium into the cell in a fixed cycle. During this process the structure of the pump changes. It is well-established that the pump has a sodium and a potassium form. But the structural differences between the two forms have remained a mystery, and researchers have been unable to explain how the pump distinguishes sodium from potassium.
Structure solves the mystery
Thanks to the international collaboration between Professor Chikashi Toyoshima’s group at the University of Tokyo and researchers from Aarhus University, the structure of the sodium-bound form of the protein has now been described. For the first time ever, the sodium ions can be studied at a resolution so high - 0.28 nanometres - that researchers can actually see the sodium ions and observe where they bind in the structure of the pump. In 2000, Professor Chikashi Toyoshima’s group described the structure of a calcium-pump for the first time, and in 2007 and 2009 research groups from Aarhus University and Toyoshima’s group described the potassium-bound form of the sodium-potassium pump.
"The new protein structure shows how the smaller sodium ions are bound and subsequently transported out of the cell, whereas the access of the slightly larger potassium ions is blocked. We now understand how the pump distinguishes between sodium and potassium at the molecular level. This is a great leap forward for research into ion pumps and may help us understand and treat serious neurological conditions associated with mutations of the sodium-potassium pump, including a form of Parkinsonism and alternating hemiplegia of childhood in which sodium binding is defective," explains Bente Vilsen, a professor at Aarhus University who spearheaded the project’s activities in Aarhus with Associate Professor Flemming Cornelius.
Impressed Nobel Prize winner
The vital pump was discovered in 1957 by Professor Jens Christian Skou of Aarhus University, who received the Nobel Prize for his discovery in 1997. The new result is the culmination of five or six decades of research aimed at the mechanism behind this vital motor of the cells.
"Years ago, when the first electron microscopic images were taken in which the enzyme was but a millimetre-sized dot at 250,000 magnifications, I thought, how on earth will we ever be able to establish the structure of the enzyme. The pump transports potassium into and sodium out of the cells, so it must be capable of distinguishing between the two ions. But until now, it has been a mystery how this was possible," says retired Professor Jens Christian Skou, who - even at 94 years of age - keeps up to date with new developments in the field of research which he initiated more than 50 years ago.
"Now, the researchers have described the structure that allows the enzyme to identify sodium and this may pave the way for a more detailed understanding of how the pump works. It is an impressive achievement and something I haven’t even dared dream of," concludes Jens Christian Skou.
(Source: eurekalert.org)
Smell the potassium: Surprising find in study of sex- and aggression-triggering vomeronasal organ
"We found two new ion channels—both of them potassium channels—through which VNO neurons are activated in mice," says Associate Investigator C. Ron Yu, Ph.D., senior author of the study. "This is quite unusual; potassium channels normally don’t play a direct role in the activation of sensory neurons."
Humans have shrunken, seemingly vestigial VNOs, but still exhibit instinctive, pre-programmed behaviors relating to reproduction and aggression. Scientists hope that an understanding of how the VNO works in mice and other lower mammals will provide clues to how these innate behaviors are triggered in humans.
The VNO works in much the same way as the main olfactory organ that provides the sense of smell. Its neurons and their input stalks, known as dendrites, are studded with specialized receptors that can be activated by contact with specific messenger-chemicals called pheromones, found mostly in body fluids. When activated, VNO receptors cause adjacent ion channels to open or close allowing ions to flood into or out of a neuron. These inflows and outflows of electric charge create voltage surges that can activate a VNO neuron, so that it signals to the brain to turn on a specific behavior.
Mutation of voltage-sensor domains (VSDs) can sometimes lead to ions leaking across the membrane through the VSDs themselves. Ion conduction through the mutated VSD of the Shaker Kv channel was coined the “omega current” in 2005 by Tombola, Pathak and Isacoff (Tombola et al., 2005). Many different mutations have been identified that result in current leaking through VSDs in many different channels. This current can be carried by a variety of ions including H+, Li+, K+, Cs+ and guanidinium. It has also been shown that naturally occurring mutations in VSDs that result in omega current leak can lead to channelopathies (diseases caused by malfunctioning ion channels, learn more about them out on wikipedia). In this post I will discuss a mutation of the Shaker Kv channel that results in omega current leak. I will address how this current arises and briefly what it can tell us about the mechanism of voltage-sensing.
Ion selectivity in neuronal signaling channels evolved twice in animals
July 26, 2012
Excitation of neurons depends on the selected influx of certain ions, namely sodium, calcium and potassium through specific channels. Obviously, these channels were crucial for the evolution of nervous systems in animals. How such channels could have evolved their selectivity has been a puzzle until now. Yehu Moran and Ulrich Technau from the University of Vienna together with Scientists from Tel Aviv University and the Woods Hole Oceanographic Institution (USA) have now revealed that voltage-gated sodium channels, which are responsible for neuronal signaling in the nerves of animals, evolved twice in higher and lower animals. These results were published in Cell Reports.
Close-up of nervous system of a transgenic polyp of the sea anemone Nematostella vectensis, in which a red fluorescent reporter gene (mCherry) is driven by the regulatory sequence of the neuronal ELAV gene. The picture shows the diffuse structure of the nervous system, but also reveals the accumulation of longitudinal axonal tracts along the eight gastric tissue folds (mesenteries). Credit: Copyright: U. Technau
The opening and closing of ion channels enable flow of ions that constitute the electrical signaling in all nervous systems. Every thought we have or every move we make is the result of the highly accurate opening and closing of numerous ion channels. Whereas the channels of most lower animals and their unicellular relatives cannot discern between sodium and calcium ions, those of higher animals are highly specific for sodium, a characteristic that is important for fast and accurate signaling in complex nervous system.
Surprising results in sea anemones and jellyfish
However, the researchers found that a group of basal animals with simple nerve nets including sea anemones and jellyfish also possess voltage-gated sodium channels, which differ from those found in higher animals, yet show the same selectivity for sodium. Since cnidarians separated from the rest of the animals more than 600 million years ago, these findings suggest that the channels of both cnidarians and higher animals originated independently twice, from ancient non-selective channels which also transmit calcium.
Since many other processes of internal cell signaling are highly dependent on calcium ions, the use of non-selective ion channels in neurons would accidently trigger various signaling systems inside the cells and will cause damage. The evolution of selectivity for sodium ions is therefore considered as an important step in the evolution of nervous systems with fast transmission. This study shows that different parts of the channel changed in a convergent manner during the evolution of cnidarians and higher animals in order to perform the same task, namely to select for sodium ions.
This demonstrates that important components for the functional nervous systems evolved twice in basal and higher animals, which suggests that more complex nervous systems that rely on such ion-selective channels could have also evolved twice independently.
Source: PHYS.ORG