Blood stem cells fight invaders, study finds

New research from the lab of Harvard Medical School professor of pathology Ulrich von Andrian, published in the November 30 edition of Cell, now suggests that HSCs’ biological role is far more versatile and dynamic. He and his colleagues have found that HSCs can travel from the bone marrow, through the blood system, and enter visceral organs where they perform reconnaissance missions in search of pathogenic invaders. Upon encountering an invader they immediately synthesize a defense, divide and mature, churning out new immune system cells such as dendritic cells and other leukocytes, right on the spot.

“This process changes the way we look at blood stem cells,” says von Andrian.

For almost five decades scientists have known that a fraction of HSCs will sometimes migrate from the bone marrow into the bloodstream. And while scientists have observed this phenomenon, they haven’t known exactly why the stem cells would do this, and what sort of itinerary they might follow once they entered the blood.

A group in von Andrian’s lab, led by postdoctoral researcher and cardiologist Steffen Massberg, decided to explore this question.

They began be extracting lymph samples from the thoracic duct of a mouse. The thoracic duct, a major component of the lymphatic system, routes the body’s excess fluids into the circulation, fluids that normally accumulate in organs. In that sense, it’s a kind of physiological storm drainage system. The group reasoned that any itinerary would eventually bring these cells into the lymph system, so it marked a logical starting point.

After screening large samples of thoracic fluid, they discovered an extremely small population of cells that, after rigorous testing, behaved identically to blood stem cells. Further tests, which involved mice genetically engineered so that their blood stem cells could be detected through fluorescent microscopy, revealed that these cells were also scattered throughout visceral organs, such as liver, heart, and lung.

“Taken all together, a picture developed suggesting that these cells migrated from the marrow and into the circulation where they would then leak out and enter the tissue,” says Massberg. “After that, the thoracic duct would empty them back into the circulation, where they could reenter the marrow. But the question was, why" What exactly are they doing"”

The group had found that the stem cells remain in the tissue for thirty-six hours before exiting into the thoracic duct. This suggested that they were conducting some kind of surveillance. To test this, Massberg and his colleagues injected a bacterial endotoxin into the mouse tissue. Within a matter of days, clusters of specialized immune cells formed in the infected areas.

“Typical immune responses deplete local specialized immune cells,” says Massberg. “It appears that the hematopoietic stem cells initiate an immune response and replenish these specialized immune cells. It’s a way of sensing local environmental disturbances and responding locally.”

But finally, the researchers identified the molecular mechanism that explained these observational data.

After residing for a while in the organ tissue, the stem cells receive a lipid signal that enables them to exit into the thoracic duct. However, the presence of endotoxin disrupts the normal signaling cascade. When the receptors on the stem-cell surface that detect the pathogens become active, the cell’s ability to receive the lipid signal is blocked. The stem cells literally get stuck in the tissue, where they are then triggered to proliferate into immune cells.

“That stem cells are actually a part of the immune system, rather than just giving rise to it, is a very provocative idea,” says von Andrian. “This opens up a number of new avenues for us to explore ways that our bodies fight pathogens.”

The researchers are now looking at ways that other common diseases, like cancer, may exploit this process.

Source: Harvard Medical School

Response to immune protein determines pathology of multiple sclerosis
New research may help reveal why different parts of the brain can come under attack in patients with multiple sclerosis (MS). According to a new study in mice with an MS-like disease, the brain's response to a protein produced by invading T cells dictates whether it's the spinal cord or cerebellum that comes under fire. The study—from researchers at the University of Maryland School of Medicine in Baltimore and Washington University in St. Louis—will be published online on October 13th in the Journal of Experimental Medicine.
Scientists pinpoint key proteins in blood stem cell replication
A family of cancer-fighting molecules helps blood stem cells in mice decide when and how to divide, say researchers at the Stanford University School of Medicine. Blocking the molecules' function spurs the normally resting cells to begin proliferating strangely - making too much of one kind of cell and not enough of another. Many types of human blood cancers involve a similar disruption in the expression of that same family of molecules.
Scientists turn human skin cells into insulin-producing cells
(PhysOrg.com) -- Researchers at the University of North Carolina at Chapel Hill School of Medicine have transformed cells from human skin into cells that produce insulin, the hormone used to treat diabetes.
Engineered stem cells carry promising ALS therapy
(PhysOrg.com) -- Using adult stem cells from bone marrow as "Trojan horses"to deliver a nurturing growth factor to atrophied muscles, Wisconsin scientists have successfully slowed the progression of ALS in rats.
Embryonic stem cells might help reduce transplantation rejection
Researchers have shown that immune-defense cells influenced by embryonic stem cell-derived cells can help prevent the rejection of hearts transplanted into mice, all without the use of immunosuppressive drugs.
Human embryonic stem cell secretions minimized tissue injury after heart attack
A novel way to improve survival and recovery rate after a heart attack was reported in the journal Stem Cell Research by scientists at Singapore's Institute of Medical Biology (IMB) and Bioprocessing Technology Institute (BTI) and The Netherlands' University Medical Center Utrecht.
Carnegie Mellon MRI technology that non-invasively locates, quantifies specific cells in the body
Magnetic resonance imaging (MRI) isn't just for capturing detailed images of the body's anatomy. Thanks to novel imaging reagents and technology developed by Carnegie Mellon University scientist Eric Ahrens, MRI can be used to visualize — with "exquisite" specificity — cell populations of interest in the living body. The ability to non-invasively locate and track cells, such as immune cells, will greatly aid the study and treatment of cancer, inflammation, and autoimmune diseases, as well as provide a tool for advancing clinical translation of the emerging field of cellular regenerative medicine, by tracking stem cells for example.
Bone marrow stem cells may help control inflammatory bowel disease
Massachusetts General Hospital (MGH) investigators have found that infusions of a particular bone marrow stem cell appeared to protect gastrointestinal tissue from autoimmune attack in a mouse model. In their report published in the journal Stem Cells, the team from the MGH Center for Engineering in Medicine report that mesenchymal stem cells (MSCs), known to control several immune system activities, allowed the regeneration of the gastrointestinal lining in mice with a genetic mutation leading to multiorgan autoimmune disease.

Blood stem cells fight invaders, study finds

Related stories:

News discussion: