Stress-Resistant Stem Cells From Fat


During liposuction patients lose a fat cells, fat-based mesenchymal stem cells, and now, according to new results from UCLA scientists, stress-enduring stem cells.

This new stem cell population has been called a Multi-lineage Stress-Enduring Adipose Tissue or Muse-AT stem cells. UCLA scientists found Muse-AT stem cells by accident when a particular machine in the laboratory malfunctioned, killing all the cells found in cells from human liposuction, with the exception on the Muse-AT stem cells.

Gregorio Chazenbalk from the UCLA Department of Obstetrics and Gynecology and his research team discovered, after further tests on Muse-AT stem cells, that they not only survive stress, but might be activated by it.

The removal of Muse-AT stem cells from the human body by means of liposuction revealed cells that express several embryonic stem cell-specific proteins (SSEA3, TR-1-60, Oct3/4, Nanog and Sox2). Furthermore, Muse-AT stem cells were able to differentiate into muscle, bone, fat, heart muscle, liver, and neuronal cells. Finally, when Chazenbalk and his group examined the properties of Muse-AT stem cells, they discovered that these stem cells could repair and regenerate tissues when transplanted back into the body after having been exposed to cellular stress.

Muse-ATs express pluripotent stem cell markers. Immunofluorescence microscopy demonstrates that Muse-AT aggregates, along with individual Muse-AT cells, express characteristic pluripotent stem cell markers, including SSEA3, Oct3/4, Nanog, Sox2, and TRA1-60. Comparatively, ASCs (right panel) derived from the same lipoaspirate under standard conditions (see above, [16] were negative for these pluripotent stem cell markers. Nuclei were stained with DAPI (blue). Original magnification, 600 X. doi:10.1371/journal.pone.0064752.g002
Muse-ATs express pluripotent stem cell markers.
Immunofluorescence microscopy demonstrates that Muse-AT aggregates, along with individual Muse-AT cells, express characteristic pluripotent stem cell markers, including SSEA3, Oct3/4, Nanog, Sox2, and TRA1-60. Comparatively, ASCs (right panel) derived from the same lipoaspirate under standard conditions (see above, [16] were negative for these pluripotent stem cell markers. Nuclei were stained with DAPI (blue). Original magnification, 600 X.
doi:10.1371/journal.pone.0064752.g002
“This population of cells lies dormant in the fat tissue until it is subjected to very harsh conditions. These cells can survive in conditions in which usually cancer cells can survive. Upon further investigation and clinical trials, these cells could prove a revolutionary treatment option for numerous diseases, including heart disease, stroke and for tissue damage and neural regeneration,” said Chazenbalk.

Purifying and isolating Muse-AT stem cells does not require the use of a cell sorter or other specialized, high-tech machinery. Muse-AT stem cell can grow in liquid suspension, where they grow as small spheres or as adherent cells that pile on top of each other to form aggregates, which is rather similar to embryonic stem cells and the embryoid bodies that they form.

Isolation and morphologic characterization of Muse-ATs. (A) Schematic of Muse-AT isolation and activation from their quiescent state by exposure to cellular stress. Muse-AT cells were obtained after 16 hours, with incubation with collagenase in DMEM medium without FCS at 4°C under very low O2 (See Methods). (B) FACS analysis demonstrates that 90% of isolated cells are both SSEA3 and CD105 positive. (C) Muse-AT cells can grow in suspension, forming spheres or cell clusters as well as individual cells (see red arrows) or (D) Muse-AT cells can adhere to the dish and form cell aggregates. Under both conditions, individual Muse-AT cells reached a diameter of approximately 10µm and cell clusters reached a diameter of up to 50µm, correlating to stem cell proliferative size capacity. doi:10.1371/journal.pone.0064752.g001
Isolation and morphologic characterization of Muse-ATs.
(A) Schematic of Muse-AT isolation and activation from their quiescent state by exposure to cellular stress. Muse-AT cells were obtained after 16 hours, with incubation with collagenase in DMEM medium without FCS at 4°C under very low O2 (See Methods). (B) FACS analysis demonstrates that 90% of isolated cells are both SSEA3 and CD105 positive. (C) Muse-AT cells can grow in suspension, forming spheres or cell clusters as well as individual cells (see red arrows) or (D) Muse-AT cells can adhere to the dish and form cell aggregates. Under both conditions, individual Muse-AT cells reached a diameter of approximately 10µm and cell clusters reached a diameter of up to 50µm, correlating to stem cell proliferative size capacity.
doi:10.1371/journal.pone.0064752.g001

We have been able to isolate these cells using a simple and efficient method that takes about six hours from the time the fat tissue is harvested,” said Chazenbalk. “This research offers a new and exciting source of fat stem cells with pluripotent characteristics, as well as a new method for quickly isolating them. These cells also appear to be more primitive than the average fat stem cells, making them potentially superior sources for regenerative medicine.”

Embryonic stem cells and induced pluripotent stem cells are the two main sources of pluripotent stem cells. However, both of these stem cells have an uncontrolled capacity for differentiation and proliferation, which leads to the formation of undesirable teratomas, which are benign tumors that can become teratocarcinomas, which are malignant tumors. According to Chazenbalk, little progress has been made in resolving this defect (I think he overstates this).

Muse-AT stem cells were discovered by a research group at Tokohu University in Japan and were isolated from skin and bone marrow rather than fat (see Tsuchiyama K, et al., J Invest Dermatol. 2013 Apr 5. doi: 10.1038/jid.2013.172). The Japanese group showed that Muse-AT stem cells do not form tumors in laboratory animals. The UCLA group was also unable to get Muse-AT stem cells to form tumors in laboratory animals, but more work is necessary to firmly establish that these neither form tumors nor enhance the formation of other tumors already present in the body.

Chazenbalk also thought that Muse-AT stem cells could provide an excellent model system for studying the effects of cellular stress and how cancer cells survive and withstand high levels of cellular stress.

Chazenbalk is understandable excited about his work, but other stem cells scientists remain skeptical that this stem cells population has the plasticity reported or that these cells are as easily isolated as Chazenbalk says.  For a more skeptical take on this paper, see here.

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mburatov

Professor of Biochemistry at Spring Arbor University (SAU) in Spring Arbor, MI. Have been at SAU since 1999. Author of The Stem Cell Epistles. Before that I was a postdoctoral research fellow at the University of Pennsylvania in Philadelphia, PA (1997-1999), and Sussex University, Falmer, UK (1994-1997). I studied Cell and Developmental Biology at UC Irvine (PhD 1994), and Microbiology at UC Davis (MA 1986, BS 1984).