Posts tagged hormone
Articles and news from the latest research reports.
The trails of light follow neurons that secrete GnRH, a master hormone that
regulates other reproductive hormones. Unusual for neurons, these sit just
outside of the brain-blood barrier, which is how they have access to the
bloodstream, where they deposit GnRH.
(Credit: O. Brock)
Target for obesity drugs comes into focus
Researchers at the University of Michigan have determined how the hormone leptin, an important regulator of metabolism and body weight, interacts with a key receptor in the brain.
Leptin is a hormone secreted by fat tissue that has been of interest for researchers in obesity and Type 2 diabetes since it was discovered in 1995. Like insulin, leptin is part of a regulatory network that controls intake and expenditure of energy in the body, and a lack of leptin or resistance to it has been linked to obesity in people.
Although there can be several complex reasons behind leptin resistance, in some cases the underlying cause is malfunction of the leptin receptor in the brain. An understanding of how leptin and its receptor interact could lead to new treatments for obesity and metabolic disorders, but the structure of this signaling complex has evaded researchers for years.
Georgios Skiniotis, a faculty member at the Life Sciences Institute and assistant professor in biological chemistry at the U-M Medical School, employed electron microscopy to obtain the first picture of the interaction between leptin and its receptor.
Skiniotis also traced similarities between the leptin receptor and other receptors of the same family, which may provide insight into new targets for treatment of other hormone-related diseases.
Testosterone increases honesty
Researchers from the University of Bonn examine the biological background of lying
Testosterone is considered THE male hormone, standing for aggression and posturing. Researchers around Prof. Dr. Armin Falk, an economist from the University of Bonn, have now been able to demonstrate that this sex hormone surprisingly also fosters social behavior. In play situations, subjects who had received testosterone clearly lied less frequently than individuals who had only received a placebo. The results have just been published in the Public Library of Science’s international online journal “PLoS ONE.”
The hormone testosterone stands for typically male attributes – it fosters the forming of the sexual characteristics, increases libido and muscle building. Women also have this sex hormone, but to a much lesser extent. “Testosterone has always been said to promote aggressive and risky behavior and posturing,” reports Prof. Dr. Bernd Weber, a neuro-scientist from the Center for Economics and Neuroscience (CENS) at the University of Bonn. More recent studies indicate, however, that this sex hormone also fosters social behavior.
(Photo: Getty Images)
Hormone in Fruit Flies Sheds Light On Diabetes Cure, Weight-Loss Drug for Humans
ScienceDaily (Aug. 9, 2012) — Manipulating a group of hormone-producing cells in the brain can control blood sugar levels in the body — a discovery that has dramatic potential for research into weight-loss drugs and diabetes treatment.
Erik Johnson uses the fruit fly, Drosophila, to look at an enzyme called AMP-activated kinase and its role in signaling the hormone that elevates the level of sugar in the blood. (Credit: Image courtesy of Wake Forest University)
In a paper published in the October issue of Genetics and available online now, neurobiologists at Wake Forest University examine how fruit flies (Drosophila) react when confronted with a decreased diet.
Reduced diet or starvation normally leads to hyperactivity in fruit flies — a hungry fly buzzes around feverishly, looking for more food. That happens because an enzyme called AMP-activated kinase stimulates the secretion of the adipokinetic hormone, which is the functional equivalent of glucagon. This hormone acts opposite of insulin, as it tells the body to release the sugar, or food, needed to fuel that hyperactivity. The body uses up its energy stores until it finds food.
But when Wake Forest’s Erik Johnson, an associate professor of biology, and his research team turned off AMP-activated kinase, the cells decreased sugar release and the hyperactive response stopped almost completely — even in the face of starvation.
"Since fruit flies and humans share 30 percent of the same genes and our brains are essentially wired the same way, it suggests that this discovery could inform metabolic research in general and diabetes research specifically," said Johnson, the study’s principal investigator. "The basic biophysical, biochemical makeup is the same. The difference in complexity is in the number of cells. Why flies are so simple is that they have approximately 100,000 neurons versus the approximately 11 billion in humans."
Medical advances as a result of this research might include:
• Diabetes research: Adipokinetic hormone is the insect equivalent to the hormone glucagon in the human pancreas. Glucagon raises blood sugar levels; insulin reduces them. However, it is difficult to study glucagon systems because the pancreatic cells are hard to pull apart. Studying how this similar system works in the fruit fly could pave the way to a drug that targets the cells that cause glucagon to tell the body to release sugar into the blood — thus reducing the need for insulin shots in diabetics.
• Weight-loss drugs: An “exercise drug” would turn on all AMP-activated kinase in the body and trick the body into thinking it was exercising. “Exercise stimulates AMP-activated kinase, so manipulation of this molecule may lead to getting the benefits of exercise without exercising,” Johnson said. In previous research published in the online journal PLoS ONE, Johnson and his colleagues found that, when you turn off AMP-activated kinase, you get fruit flies that “eat a lot more than normal flies, move around a lot less, and end up fatter.”
Source: Science Daily
A Unique On-Off Switch for Hormone Production
ScienceDaily (Feb. 23, 2012) — After we sense a threat, our brain center responsible for responding goes into gear, setting off a chain of biochemical reactions leading to the release of cortisol from the adrenal glands.
Dr. Gil Levkowitz and his team in the Molecular Cell Biology Department have now revealed a new kind of ON-OFF switch in the brain for regulating the production of a main biochemical signal from the brain that stimulates cortisol release in the body. This finding, which was recently published in Neuron, may be relevant to research into a number of stress-related neurological disorders.
This signal is corticotropin releasing hormone (CRH). CRH is manufactured and stored in special neurons in the hypothalamus. Within this small brain region the danger is sensed, the information processed and the orders to go into stress-response mode are sent out. As soon as the CRH-containing neurons have depleted their supply of the hormone, they are already receiving the directive to produce more.
The research — on zebrafish — was performed in Levkowitz’s lab and spearheaded by Dr. Liat Amir-Zilberstein together with Drs. Janna Blechman, Adriana Reuveny and Natalia Borodovsky and Maayan Tahor. The team found that a protein called Otp is involved in several stages of CRH production. As well as directly activating the genes encoding CRH, it also regulates the production of two different receptors on the neurons’ surface for receiving and relaying CRH production signals — in effect, ON and OFF switches.
The team found that both receptors are encoded in a single gene. To get two receptors for the price of one, Otp regulates a gene-editing process known as alternative splicing, in which some of the elements in the sequence encoded in a gene can be “cut and pasted” to make slightly different “sentences.” In this case, it generates two variants of a receptor called PAC1: The short version produces the ON receptor; the long version, containing an extra sequence, encodes the OFF receptor. The researchers found that as the threat passed and the supply of CRH was replenished, the ratio between the two types of PAC1 receptor on the neurons’ surface gradually changed from more ON to mostly OFF. In collaboration with Drs Laure Bally-Cuif and William Norton of the Institute of Neurobiology Alfred Fessard at the Centre National de la Recherche Scientifique (CNRS) in France, the researchers showed that blocking the production of the long receptor variant causes an anxiety-like behavior in zebrafish.
Together with Drs. Alon Chen and Yehezkel Sztainberg of the Neurobiology Department, Levkowitz’s team found the same alternatively-spliced switch in mice. This conservation of the mechanism through the evolution of fish and mice implies that a similar means of turning CRH production on and off exists in the human brain.
Faulty switching mechanisms may play a role in a number of stress-related disorders. The action of the PAC1 receptor has recently been implicated in post-traumatic stress disorder, as well as in schizophrenia and depression. Malfunctions in alternative splicing have also been associated with epilepsy, mental retardation, bipolar disorder and autism.
Source: Science Daily