Tag: ion channels

How Oestrogen can Trigger Nerve Impulses in Milliseconds

Photo by Julian Jagtenberg on Pexels

Oestrogen, the major female ovarian hormone, can trigger nerve impulses within milliseconds to regulate a variety of physiological processes. At Baylor College of Medicine, Louisiana State University and collaborating institutions, researchers discovered that oestrogen’s fast actions are mediated by the coupling of the oestrogen receptor-alpha (ER-alpha) with an ion channel protein called Clic1.

Clic1 controls the fast flux of electrically charged chloride ions through the cell membrane, which neurons use for receiving, conducting and transmitting signals. The researchers propose that interacting with the ER-alpha-Clic1 complex enables oestrogen to trigger fast neuronal responses through Clic1 ion currents. The study appeared in Science Advances.

“Oestrogen can act in the brain to regulate a variety of physiological processes, including female fertility, sexual behaviours, mood, reward, stress response, cognition, cardiovascular activities and body weight balance. Many of these functions are mediated by oestrogen binding to one of its receptors, ER-alpha,” said co-corresponding author Dr Yong Xu, professor of pediatrics – nutrition and associate director for basic sciences at the USDA/ARS Children’s Nutrition Research Center at Baylor. 

Fast and slow

It is well known that, upon stimulation by oestrogen, ER-alpha enters the cell nucleus where it mediates the transcription of genes. This classical mode of action as a nuclear receptor takes minutes to hours.

“Oestrogen also can change the firing activity of neurons in a manner of milliseconds, but it was not clear how this happens,” Xu said. “In this case, it did not make sense to us that the minutes-long nuclear receptor function of ER-alpha was involved in such a rapid action. We explored the possibility that ion channels, proteins in the cell membrane that regulate the fast flux of ions, mediated oestrogen’s quick actions.”

In the current study, working with cell lines and animal models, the team searched for cell membrane proteins that interact with ER-alpha. They found that protein Clic1, for chloride intracellular channel protein-1, can physically interact with ER-alpha. Clic1has been implicated in the regulation of neuronal excitability, so the researchers considered it a candidate to mediate oestrogen-triggered fast actions.

“We discovered that oestrogen enhances Clic1-mediated ion currents, and eliminating oestrogen reduced such currents,” Xu said. “In addition, Clic1 currents are required for oestrogen to induce rapid responses in neurons. Also, disrupting the Clic1 gene in animal models blunted oestrogen regulation of female body weight balance.”

The findings suggest that other nuclear receptors could also interact with ion channels, a possibility the researchers look forward to studying in the future.

“This study was conducted with female mice. However, Clic1 is also present in males. We are interested in investigating its role in male physiology,” Xu said.

Chloride channels are not as well studied as other ion channels, such as potassium, sodium or calcium channels. “We are among the first to study the role Clic1 plays in female physiology,” Xu said. “We hope that our findings will inspire other groups in the field to expand these promising investigations.”

Source: Baylor College of Medicine

Study Resolves Long-standing Question on Gating of Ion Channels

Source: CC0

Ion channels play a crucial role in many cellular processes, including neuronal communication, muscle contraction or cell proliferation. Most multi subunit ion channels exist in two functional states, either closed or open. During gating, one should expect that all subunits undergo conformational changes – but there are no intermediate conduction levels. To find out why, researchers from the University of Vienna and the Washington University in St. Louis created a smart model system. The study is currently published in Nature Communications.

Ion channels are membrane proteins that regulate the electrical activity of cells. In this study the scientific team investigated the inwardly rectifying potassium channel Kir2. This channel is crucial for maintaining a negative membrane potential in many cells. These channels are promising drug targets for treatment of cardiovascular diseases. To foster drug development, a detailed understanding of the gating mechanism is important.

Intelligent model system & innovative methods

“We designed a model system that allowed us to visualise the gating of individual subunits and track conductance changes,” explains Grigory Maksaev from the Washington University in St. Louis. As a model system, the inwardly rectifying potassium channel Kir2 was used. This channel is crucial for maintaining a negative membrane potential in many cells. “We introduced an acidic residue near the channel gate. This led to novel states, so-called sub-conductance states” explains Eva Plessl from the Department of Pharmaceutical Sciences, University of Vienna. The life times of these sub-states were long enough to resolve them experimentally. Each of the observed sub-states represents a distinct subunit conformation. Interestingly, the sub-state occupancy is titratable by pH. “This suggests that protonation or deprotonation of individual acidic residues causes this phenomenon,” explains Sun-Joo Lee from the Washington University in St. Louis.

Sour is…less conductive

“Molecular dynamics simulations with different protonation states of the acidic residue support this finding,” explains Anna Weinzinger from the Department of Pharmaceutical Sciences, University of Vienna. The study reveals that each subunit gating transition leads to conductance level changes. This suggests that for a fully open channel, all subunits must move together. “By designing a smart model system, we have answered a long-standing question about ion channel gating,” explains Colin Nichols from the Washington University in St. Louis.

Source: University of Vienna

Why Antidepressants Take Weeks to Provide Relief

A healthy neuron.
A healthy neuron. Credit: NIH

The findings of a study published in Science Translational Medicine paint a new picture of how current antidepressant drugs work and suggest a new drug target in depression. As with most drugs, antidepressants were developed through trial and observation. Some 40% of patients with the disorder don’t respond adequately to the drugs, and when they do work, antidepressants take weeks to provide relief. Why this is has remained largely a mystery.

To figure out why these drugs have a delayed onset, the team examined a mouse model of chronic stress that leads to changes in behaviours controlled by the hippocampus. The hippocampus is vulnerable to stress and atrophies in people with major depression or schizophrenia. Mice exposed to chronic stress show cognitive deficits, a hallmark of impaired hippocampal function.

“Cognitive impairment is a key feature of major depressive disorder, and patients often report that difficulties at school and work are some of the most challenging parts of living with depression. Our ability to model cognitive impairment in lab mice gives us the chance to try and understand how to treat these kinds of symptoms,” said Professor Dane Chetkovich, MD, PhD, who led the study.

The study focussed on an ion transporter channel in nerve cell membranes known as the HCN channelPrevious work has shown HCN channels have a role in depression and separately to have a role in regulation of cognition. According to the authors, this was the first study to explicitly link the two observations.

Examination of postmortem hippocampal samples led the team to establish that HCN channels are more highly expressed in people with depression. HCN channel activity is modulated by a small signaling molecule called cAMP, which is increased by antidepressants. The team used protein receptor engineering to increase cAMP signaling in mice and establish in detail the effects this has on hippocampal HCN channel activity and, through that connection, on cognition.

Turning up cAMP was found to initially increase HCN channel activity, limit the intended effects of antidepressants and negatively impact cognition (as measured in standard lab tests).

However, a total reversal took place over a period of some weeks. Previous work by the researchers had established that an auxiliary subunit of the HCN channel, TRIP8b, is essential for the channel’s role in regulating animal behaviour. The new study shows that, over weeks, a sustained increase in cAMP starts to interfere with TRIP8b’s ability to bind to the HCN channel, thereby quieting the channel and restoring cognitive abilities.

“This leaves us with acute and chronic changes in cAMP, of the sort seen in antidepressant drug therapy, seen here for the first time to be regulating the HCN channel in the hippocampus in two distinct ways, with opposing effects on behaviour,” Prof Chetkovich said. “This appears to carry promising implications for new drug development, and targeting TRIP8b’s role in the hippocampus more directly could help to more quickly address cognitive deficits related to chronic stress and depression.”

Source: Vanderbilt University

Human Neurons Differ From Animal Ones in a Surprising Way

A healthy neuron. Credit: National Institutes of Health

Human Neurons Differ From Animal Ones in a Surprising WayIn a surprising new finding published in Nature, neuroscientists have shown that human neurons have a much smaller number of ion channels than expected, compared to the neurons of other mammals.

Ion channels are integral membrane proteins that contain pathways through which ions can flow. By shifting between closed and open conformational states (‘gating’ process), they control passive ion flow through the plasma membrane. 

The researchers hypothesise that lower channel density may have helped the human brain evolve energy efficiency, letting it divert resources elsewhere.

“If the brain can save energy by reducing the density of ion channels, it can spend that energy on other neuronal or circuit processes,” said senior author Mark Harnett, an associate professor of brain and cognitive sciences.

Analysing neurons from 10 different mammals, the researchers identified a “building plan” that holds true for every examined species — save humans. They found that as the size of neurons increases, the density of channels found in the neurons also increases.

However, human neurons proved to be a striking exception to this rule.

“Previous comparative studies established that the human brain is built like other mammalian brains, so we were surprised to find strong evidence that human neurons are special,” said lead author and former MIT graduate student Lou Beaulieu-Laroche.

Neurons in the mammalian brain can receive electrical signals from thousands of other cells, and that input determines whether or not they will fire an electrical impulse called an action potential. In 2018, Prof Harnett and Beaulieu-Laroche discovered that human and rat neurons differ in some of their electrical properties, primarily in dendrites.

One of the findings from that study was that human neurons had a lower density of ion channels than neurons in the rat brain. The researchers were surprised by this observation, as ion channel density was generally assumed to be constant across species. In their new study, Harnett and Beaulieu-Laroche decided to compare neurons from several different mammalian species to see if they could find any patterns that governed the expression of ion channels. They studied two types of voltage-gated potassium channels and the HCN channel, which conducts both potassium and sodium, in layer 5 pyramidal neurons, a type of excitatory neurons found in the brain’s cortex.

They were able to obtain brain tissue from a range of 10 mammalian species, including human tissue removed from patients with epilepsy during brain surgery. This variety allowed the researchers to cover a range of cortical thicknesses and neuron sizes across the mammalian kingdom.

In nearly every mammalian species the researchers examined, the density of ion channels increased as the size of the neurons went up. Human neurons bucked this trend, having a much lower density of ion channels than expected.

The increase in channel density across species was a surprise, Prof Harnett explained, because the more channels there are, the more energy is required to pump ions in and out of the cell. However, it started to make sense once the researchers began thinking about the number of channels in the overall volume of the cortex, he said.

In the tiny brain of the Etruscan shrew, which is packed with very small neurons, there are more neurons in a given volume of tissue than in the same volume of tissue from the rabbit brain, which has much larger neurons. But because the rabbit neurons have a higher density of ion channels, the density of channels in a given volume of tissue is the same in both species, or any of the nonhuman species the researchers analysed.

“This building plan is consistent across nine different mammalian species,” Prof Harnett said. “What it looks like the cortex is trying to do is keep the numbers of ion channels per unit volume the same across all the species. This means that for a given volume of cortex, the energetic cost is the same, at least for ion channels.”

The human brain represents a striking deviation from this building plan, however. Instead of increased density of ion channels, the researchers found a dramatic decrease in the expected density of ion channels for a given volume of brain tissue.

The researchers believe this lower density may have evolved as a way to expend less energy on pumping ions, which allows the brain to use that energy for something else, like creating more complicated synaptic connections between neurons or firing action potentials at a higher rate.

“We think that humans have evolved out of this building plan that was previously restricting the size of cortex, and they figured out a way to become more energetically efficient, so you spend less ATP per volume compared to other species,” Prof Harnett said.

He now hopes to study where that extra energy might be going, and whether there are specific gene mutations that help neurons of the human cortex achieve this high efficiency. The researchers are also interested in exploring whether primate species that are more closely related to humans show similar decreases in ion channel density.

Source: Massachusetts Institute of Technology