Missing link found between brain, immune system; major disease implications
- Date:
- June 1, 2015
- Source:
- University of Virginia Health System
- Summary:
- In a stunning discovery that overturns decades of textbook teaching, researchers have determined that the brain is directly connected to the immune system by vessels previously thought not to exist. The discovery could have profound implications for diseases from autism to Alzheimer's to multiple sclerosis.
Maps of the lymphatic
system: old (left) and updated to reflect UVA's discovery.
Credit: University of
Virginia Health System
In a stunning discovery that
overturns decades of textbook teaching, researchers at the University of
Virginia School of Medicine have determined that the brain is directly connected
to the immune system by vessels previously thought not to exist. That such
vessels could have escaped detection when the lymphatic system has been so
thoroughly mapped throughout the body is surprising on its own, but the true
significance of the discovery lies in the effects it could have on the study and
treatment of neurological diseases ranging from autism to Alzheimer's disease to
multiple sclerosis.
"Instead of asking, 'How do we study the immune
response of the brain?' 'Why do multiple sclerosis patients have the immune
attacks?' now we can approach this mechanistically. Because the brain is like
every other tissue connected to the peripheral immune system through meningeal
lymphatic vessels," said Jonathan Kipnis, PhD, professor in the UVA Department
of Neuroscience and director of UVA's Center for Brain Immunology and Glia
(BIG). "It changes entirely the way we perceive the neuro-immune interaction. We
always perceived it before as something esoteric that can't be studied. But now
we can ask mechanistic questions."
"We believe that for every neurological disease that has an immune component to it, these vessels may play a major role," Kipnis said. "Hard to imagine that these vessels would not be involved in a [neurological] disease with an immune component."
New Discovery in Human Body
Kevin Lee, PhD, chairman of the UVA Department of Neuroscience, described his reaction to the discovery by Kipnis' lab: "The first time these guys showed me the basic result, I just said one sentence: 'They'll have to change the textbooks.' There has never been a lymphatic system for the central nervous system, and it was very clear from that first singular observation -- and they've done many studies since then to bolster the finding -- that it will fundamentally change the way people look at the central nervous system's relationship with the immune system."
Even Kipnis was skeptical initially. "I really did not believe there are structures in the body that we are not aware of. I thought the body was mapped," he said. "I thought that these discoveries ended somewhere around the middle of the last century. But apparently they have not."
'Very Well Hidden'
The discovery was made possible by the work of Antoine Louveau, PhD, a postdoctoral fellow in Kipnis' lab. The vessels were detected after Louveau developed a method to mount a mouse's meninges -- the membranes covering the brain -- on a single slide so that they could be examined as a whole. "It was fairly easy, actually," he said. "There was one trick: We fixed the meninges within the skullcap, so that the tissue is secured in its physiological condition, and then we dissected it. If we had done it the other way around, it wouldn't have worked."
After noticing vessel-like patterns in the distribution of immune cells on his slides, he tested for lymphatic vessels and there they were. The impossible existed. The soft-spoken Louveau recalled the moment: "I called Jony [Kipnis] to the microscope and I said, 'I think we have something.'"
As to how the brain's lymphatic vessels managed to escape notice all this time, Kipnis described them as "very well hidden" and noted that they follow a major blood vessel down into the sinuses, an area difficult to image. "It's so close to the blood vessel, you just miss it," he said. "If you don't know what you're after, you just miss it."
"Live imaging of these vessels was crucial to demonstrate their function, and it would not be possible without collaboration with Tajie Harris," Kipnis noted. Harris, a PhD, is an assistant professor of neuroscience and a member of the BIG center. Kipnis also saluted the "phenomenal" surgical skills of Igor Smirnov, a research associate in the Kipnis lab whose work was critical to the imaging success of the study.
Alzheimer's, Autism, MS and Beyond
The unexpected presence of the lymphatic vessels raises a tremendous number of questions that now need answers, both about the workings of the brain and the diseases that plague it. For example, take Alzheimer's disease. "In Alzheimer's, there are accumulations of big protein chunks in the brain," Kipnis said. "We think they may be accumulating in the brain because they're not being efficiently removed by these vessels." He noted that the vessels look different with age, so the role they play in aging is another avenue to explore. And there's an enormous array of other neurological diseases, from autism to multiple sclerosis, that must be reconsidered in light of the presence of something science insisted did not exist.
"We believe that for every neurological disease that has an immune component to it, these vessels may play a major role," Kipnis said. "Hard to imagine that these vessels would not be involved in a [neurological] disease with an immune component."
New Discovery in Human Body
Kevin Lee, PhD, chairman of the UVA Department of Neuroscience, described his reaction to the discovery by Kipnis' lab: "The first time these guys showed me the basic result, I just said one sentence: 'They'll have to change the textbooks.' There has never been a lymphatic system for the central nervous system, and it was very clear from that first singular observation -- and they've done many studies since then to bolster the finding -- that it will fundamentally change the way people look at the central nervous system's relationship with the immune system."
Even Kipnis was skeptical initially. "I really did not believe there are structures in the body that we are not aware of. I thought the body was mapped," he said. "I thought that these discoveries ended somewhere around the middle of the last century. But apparently they have not."
'Very Well Hidden'
The discovery was made possible by the work of Antoine Louveau, PhD, a postdoctoral fellow in Kipnis' lab. The vessels were detected after Louveau developed a method to mount a mouse's meninges -- the membranes covering the brain -- on a single slide so that they could be examined as a whole. "It was fairly easy, actually," he said. "There was one trick: We fixed the meninges within the skullcap, so that the tissue is secured in its physiological condition, and then we dissected it. If we had done it the other way around, it wouldn't have worked."
After noticing vessel-like patterns in the distribution of immune cells on his slides, he tested for lymphatic vessels and there they were. The impossible existed. The soft-spoken Louveau recalled the moment: "I called Jony [Kipnis] to the microscope and I said, 'I think we have something.'"
As to how the brain's lymphatic vessels managed to escape notice all this time, Kipnis described them as "very well hidden" and noted that they follow a major blood vessel down into the sinuses, an area difficult to image. "It's so close to the blood vessel, you just miss it," he said. "If you don't know what you're after, you just miss it."
"Live imaging of these vessels was crucial to demonstrate their function, and it would not be possible without collaboration with Tajie Harris," Kipnis noted. Harris, a PhD, is an assistant professor of neuroscience and a member of the BIG center. Kipnis also saluted the "phenomenal" surgical skills of Igor Smirnov, a research associate in the Kipnis lab whose work was critical to the imaging success of the study.
Alzheimer's, Autism, MS and Beyond
The unexpected presence of the lymphatic vessels raises a tremendous number of questions that now need answers, both about the workings of the brain and the diseases that plague it. For example, take Alzheimer's disease. "In Alzheimer's, there are accumulations of big protein chunks in the brain," Kipnis said. "We think they may be accumulating in the brain because they're not being efficiently removed by these vessels." He noted that the vessels look different with age, so the role they play in aging is another avenue to explore. And there's an enormous array of other neurological diseases, from autism to multiple sclerosis, that must be reconsidered in light of the presence of something science insisted did not exist.
Story Source:
The above post is reprinted from materials provided by University of Virginia Health System. Note: Materials may be edited for content and length.
The above post is reprinted from materials provided by University of Virginia Health System. Note: Materials may be edited for content and length.
Journal Reference:
- Antoine Louveau, Igor Smirnov, Timothy J. Keyes, Jacob D. Eccles, Sherin J. Rouhani, J. David Peske, Noel C. Derecki, David Castle, James W. Mandell, Kevin S. Lee, Tajie H. Harris, Jonathan Kipnis. Structural and functional features of central nervous system lymphatic vessels. Nature, 2015; DOI: 10.1038/nature14432
Cite This
Page:
University of Virginia Health System. "Missing link found
between brain, immune system; major disease implications." ScienceDaily.
ScienceDaily, 1 June 2015.
Self-Propagative Replication of Ab Oligomers Suggests Potential
Transmissibility in Alzheimer Disease
Received July 24, 2014; Accepted September 16, 2014; Published November 3,
2014
*** Singeltary comment ***
Thursday, October 1, 2015
Alzheimergate, re-Evidence for human transmission of amyloid-β pathology
and cerebral amyloid angiopathy, Singeltary Submission to Nature
TSS
No comments:
Post a Comment