Vicious circle leads to loss of brain cells in old age
Researchers determine how dangerous inflammations in the brain are caused
Science Daily/August 31, 2018
University of Bonn
The so-called CB1 receptor is responsible for the intoxicating effect of cannabis. However, it appears to act also as a kind of "sensor" with which neurons measure and control the activity of certain immune cells in the brain. A recent study by the University of Bonn at least points in this direction. If the sensor fails, chronic inflammation may result -- probably the beginning of a dangerous vicious circle. The publication appears in the journal Frontiers in Molecular Neuroscience.
The activity of the so-called microglial cells plays an important role in brain aging. These cells are part of the brain's immune defense: For example, they detect and digest bacteria, but also eliminate diseased or defective nerve cells. They also use messenger substances to alert other defense cells and thus initiate a concerted campaign to protect the brain: an inflammation.
This protective mechanism has undesirable side effects; it can also cause damage to healthy brain tissue. Inflammations are therefore usually strictly controlled. "We know that so-called endocannabinoids play an important role in this," explains Dr. Andras Bilkei-Gorzo from the Institute of Molecular Psychiatry at the University of Bonn. "These are messenger substances produced by the body that act as a kind of brake signal: They prevent the inflammatory activity of the glial cells."
Endocannabinoids develop their effect by binding to special receptors. There are two different types, called CB1 and CB2. "However, microglial cells have virtually no CB1 and very low level of CB2 receptors," emphasizes Bilkei-Gorzo. "They are therefore deaf on the CB1 ear. And yet they react to the corresponding brake signals -- why this is the case, has been puzzling so far."
Neurons as "middlemen"
The scientists at the University of Bonn have now been able to shed light on this puzzle. Their findings indicate that the brake signals do not communicate directly with the glial cells, but via middlemen -- a certain group of neurons, because this group has a large number of CB1 receptors. "We have studied laboratory mice in which the receptor in these neurons was switched off," explains Bilkei-Gorzo. "The inflammatory activity of the microglial cells was permanently increased in these animals."
In contrast, in control mice with functional CB1 receptors, the brain's own defense forces were normally inactive. This only changed in the present of inflammatory stimulus. "Based on our results, we assume that CB1 receptors on neurons control the activity of microglial cells," said Bilkei-Gorzo. "However, we cannot yet say whether this is also the case in humans."
This is how it might work in mice: As soon as microglial cells detect a bacterial attack or neuronal damage, they switch to inflammation mode. They produce endocannabinoids, which activate the CB1 receptor of the neurons in their vicinity. This way, they inform the nerve cells about their presence and activity. The neurons may then be able to limit the immune response. The scientists were able to show that neurons similarly regulatory the other major glial cell type, the astroglial cells.
During ageing the production of cannabinoids declines reaching a low level in old individuals. This could lead to a kind of vicious circle, Bilkei-Gorzo suspects: "Since the neuronal CB1 receptors are no longer sufficiently activated, the glial cells are almost constantly in inflammatory mode. More regulatory neurons die as a result, so the immune response is less regulated and may become free-running."
It may be possible to break this vicious circle with drugs in the future. It is for instance hoped that cannabis will help slow the progression of dementia. Its ingredient, tetrahydrocannabinol (THC), is a powerful CB1 receptor activator -- even in low doses free from intoxicating effect. Last year, the researchers from Bonn and colleagues from Israel were able to demonstrate that cannabis can reverse the aging processes in the brains of mice. This result now suggest that an anti-inflammatory effect of THC may play a role in its positive effect on the ageing brain.
https://www.sciencedaily.com/releases/2018/08/180831130120.htm
Cannabis: Non-addictive pathway to pain relief?
Medicinal properties of cannabis examined
January 12, 2017
Science Daily/Oregon Health & Science University
OHSU research suggests an avenue for developing treatments for chronic pain that harness the medicinal properties of cannabis while minimizing the threat of addiction.
The study, conducted in a rodent model, provides additional rationale for the development of therapeutics using cannabinoid receptors to treat chronic pain, which afflicts about 30 percent of the U.S. population. OHSU investigators studied the function of two forms of cell membrane receptors that bind cannabinoids that occur naturally within the body, called endocannabinoids.
"It may be an avenue where we can get better pain medications that are not addictive," said senior author Susan Ingram, Ph.D., an associate professor of neurosurgery in the OHSU School of Medicine.
Ingram and colleagues report the treatment of chronic pain has challenged the medical system, with medications that are ineffective or create serious side effects: "However, emerging data indicate that drugs that target the endocannabinoid system might produce analgesia with fewer side effects compared with opioids."
The body's endocannabinoid system comprises receptors, endocannabinoid molecules and enzymes that make and degrade the endocannabinoids located in the brain and throughout the central and peripheral nervous system. The research team focused on two cannabinoid receptors, known as CB1 and CB2, in the rostral ventromedial medulla -- a group of neurons located in the brainstem known to modulate pain. The study is the first to examine CB1 and CB2 receptor function at the membrane level in late adolescent and adult neurons.
The researchers observed that chronic inflammatory pain increased activity of CB2 receptors and decreased CB1 activity. Cannabis activates both CB1 and CB2 receptors equally. The study suggests that selective activation of CB2 receptors contributes to the medicinal benefit of cannabis while minimizing the propensity of the other cannabinoid receptor, CB1, to induce tolerance and withdrawal. Ingram said the next phase of the research will further explore this area of brain circuitry, which ultimately could lead to the development of a new class of pain medications.
Co-authors include lead author Ming-Hua Li, Ph.D., and Katherine L. Suchland, both with the Department of Neurological Surgery, OHSU School of Medicine.
The study was funded by grants from the National Institutes of Health (DA035316 and R56NS093894) and American Heart Association (13SDG14590005, MH.L.).
https://www.sciencedaily.com/releases/2017/01/170112130145.htm