Allergic response tied to lipid molecules in cell membrane

The team studied clusters of cholesterol-rich lipid molecules that they believe serve as platforms for the receptors that receive antibodies, the proteins that protect the body from allergens. In this case, the team examined IgE antibodies, which upon binding to their receptors initiate a cell's release of histamine--the substance that causes the unpleasant, but beneficial, mucous production, congestion, and itchiness associated with allergies. "This research is basically the molecular foundation for why many people sneeze in the spring," said Ahmed Heikal, an associate professor in the Department of Bioengineering and a leader of the project.

While the idea that lipid clusters--also known as lipid domains--are involved in the allergic response is not new, the Penn State team is the first to document this connection in a living cell under physiological conditions. "No one has observed the domains in action because they are too small and too transient--held together by very weak molecular interactions--to be viewed with a light microscope," said Erin Sheets, a Penn State assistant professor of chemistry who also is a leader of the project. "To overcome this challenge," added Heikal, "we used a combination of imaging and spectroscopy techniques that we are developing in our laboratories.

In their experiment, the researchers first labeled the cell membrane and IgE antibodies with two different fluorescent tags. Next, they introduced an allergen and watched as it bound to receptors on the cell membrane, thus initiating an allergic response.

But to demonstrate that this activity was taking place within the lipid domain, the researchers had to take advantage of a property of fluorescence, called fluorescence lifetime, in which molecules are excited with very short laser pulses. The length of time a molecule remains in its excited state before emitting a photon--the fluorescence lifetime--provides unique information about the fluorescently-labeled molecule's environment and its chemical structure. For example, a particular molecule might relax to its lowest-energy state quickly or slowly depending on whether it is exposed to a solvent.

"We previously showed that our fluorescently-labeled membrane probe has a longer lifetime within a cholesterol-rich lipid domain," said Sheets. "Here we show that changes in this lifetime follow the changes that occur during the first steps in the allergic response process. Our results also show that lipid domains in the cell membrane associate with IgE antibodies and their receptors in the initial stages of an allergic reaction."

In the future, Sheets and Heikal plan to apply the team's discoveries to a project involving aging. During the aging process, T cells, which protect the body from foreign substances like viruses and cancer cells, can lose their ability to signal effectively. Sheets and Heikal plan to use these fluorescence-lifetime imaging tools to examine the structure and integrity of T-cell membranes with a goal of determining why they lose their knack for signalling and how this problem can be corrected.

"We want to compare the effectiveness of signaling in young T cells, which clear out debris quickly, to old T cells, which are not as efficient," said Sheets. "I think it will be a pretty cool application of our technique."

Source: Penn State

Zero grip for bacteria
Patients suffering from kidney problems cannot filter the blood to remove body wastes. Some even have to go to the hospital several times a week to undergo haemodialysis (cleansing of the blood) – something which is extremely time-consuming.
'Nano-Keys' Bind Cell Receptors and Trigger Allergic Reactions
The tumblers of life continue to click as Cornell University researchers have fabricated a set of "nano-keys" on the molecular scale to interact with receptors on cell membranes and trigger larger-scale responses within cells -- such as the release of histamines in an allergic response.
Scientists use new simulation methods to observe single events of membrane fusion with molecular resolution
The fusion of membranes is essential for many processes in the human body, for instance, in the communication between nerve cells. A single fusion event occurs on the nanometer scale and takes less than a millisecond. Using computer simulations, scientists at the Max Planck Institute of Colloids and Interfaces have now been able to observe single fusion events with molecular resolution. The simulations are based on new computer algorithms by which one can investigate two large membranes which contain more that ten thousand lipid molecules surrounded by about three million water molecules. These simulations reveal that the fusion process can be controlled by the initial tensions within the membranes. Fusion occurs only at intermediate tensions but, when it occurs, it happens extremely quickly and is completed within 200 nanoseconds.
Low levels of good cholesterol linked to memory loss, dementia risk
Low levels of high-density lipoproteins (HDL) — the "good" cholesterol — in middle age may increase the risk of memory loss and lead to dementia later in life, researchers reported in Arteriosclerosis, Thrombosis and Vascular Biology: Journal of the American Heart Association.
Nanotubes could help study retrovirus transmission between human cells
Recent findings by medical researchers indicate that naturally occurring nanotubes may serve as tunnels that protect retroviruses and bacteria in transit from diseased to healthy cells — a fact that may explain why vaccines fare poorly against some invaders.
Nanotubes could aid understanding of retrovirus transmission between human cells
Recent findings by medical researchers indicate that naturally occurring nanotubes may serve as tunnels that protect retroviruses and bacteria in transit from diseased to healthy cells — a fact that may explain why vaccines fare poorly against some invaders.

Overcoming Drug Resistance—Nanoparticles Trigger Built-In Cell-Death Signal
One of the most vexing problems in treating cancer is the propensity of tumors to develop resistance to a wide range of anticancer drugs. Over 70 percent of ovarian cancer patients, for example, have drug-resistant tumors at the time of their initial diagnosis, and virtually all patients who relapse have drug-resistant tumors.
Vitamin supplement little more than 'snake oil'
A popular vitamin supplement is being advertised with claims that are demonstrably untrue, as revealed by research published in the open access journal BMC Pharmacology.

Allergic response tied to lipid molecules in cell membrane

Related stories:

News discussion: