Researchers decipher how the body controls stem cells – Phys.Org

By Dr. Matthew Watson

March 15, 2017 Credit: Universit du Luxembourg

Stem cells are unspecialised cells that can develop into any type of cell in the human body. So far, however, scientists only partially understand how the body controls the fate of these all-rounders, and what factors decide whether a stem cell will differentiate, for example, into a blood, liver or nerve cell. Researchers from the Luxembourg Centre for Systems Biomedicine (LCSB) of the University of Luxembourg and an international team have now identified an ingenious mechanism by which the body orchestrates the regeneration of red and white blood cells from progenitor cells. "This finding can help us to improve stem cell therapy in future," says Dr. Alexander Skupin, head of the "Integrative Cell Signalling" group of LCSB.

Although all cells in an organism carry the same genetic blueprints the same DNA some of them act as blood or bone cells, for example, while others function as nerve or skin cells. Researchers already understand quite well how individual cells work. But how an organism is able to create such a diversity of cells from the same genetic template and how it manages to relocate them to wherever they are needed in the body is still largely unknown. In order to learn more about this process, Alexander Skupin and his team treated blood stem cells from mice with growth hormones and then watched closely how these progenitor cells behaved during their differentiation into white or red blood cells. The researchers observed that the cells' transformation does not occur in linear, targeted fashion, but rather more opportunistically. Each progenitor cell adapts to the needs of its environment and integrates itself into the body where new cells are needed. "So, it is not as though the cell takes a ticket at the beginning of its differentiation and then travels straight to its destination. Rather, it gets off frequently to look around and see which line is best to take," Alexander Skupin explains.

By this clever mechanism, a multicellular organism can adapt the regrowth of new cells to its current needs. "Before progenitor cells differentiate once and for all, they first lose their stem cell character and then check, as it were, which cell line is currently in demand. Only then do they develop into the cell type that best suits their characteristics and which prevails in their environment," Alexander Skupin says. The researcher likens this step to a game of roulette, where the different types of cells can be thought of as the differently numbered slots in the roulette wheel that catch the ball. "When the cells lose their stem cell character, they are quasi thrown into the roulette wheel, where they first bounce around aimlessly. Only when they have found the right environment do the cells then drop into that niche like the roulette ball falling into a numbered slot and differentiate definitively." This way, the body can orchestrate its cell regeneration and at the same time prevent stem cells from being misdirected too early. "Even if a cell takes a wrong turn, it is ultimately sorted out again if its characteristics are unsuitable for the niche, or slot, it has landed in," says Skupin.

With their study, Alexander Skupin and his team have shown for the first time that a progenitor cell's fate is not clearly predetermined and does not follow a straight line. "This observation contradicts the current doctrine that stem cells are programmed to follow a certain lineage from the beginning," Alexander Skupin says. The researcher is furthermore convinced that the processes are similar for other progenitor cells. "In the lab, we have observed the same differentiation pattern in so-called iPS cells, or induced pluripotent stem cells, which can transform into many different types of cells."

This knowledge can help the researchers to improve the effectiveness of therapies in future. Stem cell therapy involves administering a patient his or her own body's stem cells in order to replace other cells that have died as a result of an affliction such as Parkinson's disease. While this promising treatment method has been intensively researched over many years, there has so far been only limited practical success in endogenous stem cell therapy. It is also highly controversial, since it is frequently accompanied by severe side effects and it cannot be ruled out that some cells might degenerate and lead to cancer. "Because we now have a better understanding of how the body influences the direction in which stem cells differentiate, we can hopefully control this process better in future," Alexander Skupin concludes.

Explore further: Genetic factors control regenerative properties of blood-forming stem cells

More information: Mitra Mojtahedi et al. Cell Fate Decision as High-Dimensional Critical State Transition, PLOS Biology (2016). DOI: 10.1371/journal.pbio.2000640

Researchers from the UCLA Department of Medicine, Division of Hematology Oncology and the Eli and Edythe Broad Center of Regenerative Medicine and Stem Cell Research at UCLA have published two studies that define how key ...

To date, it has been assumed that the differentiation of stem cells depends on the environment they are embedded in. A research group at the University of Basel now describes for the first time a mechanism by which hippocampal ...

New University of Otago research is providing fresh insights into how a patient's adult stem cells could best be used to regenerate their diseased hearts.

Though immune therapy and regenerative medicine are promising areas of research for future medical therapies, they are limited today by the difficulty of creating stem cells, and scientists around the world are searching ...

Hematopoietic stem cells (HSCs) can differentiate into all of the different types of cells that comprise the blood and immune cell lineages. HSC transplantation is the only effective treatment for certain blood disorders; ...

A*STAR researchers and colleagues have developed a method to isolate and expand human heart stem cells, also known as cardiac progenitor cells, which could have great potential for repairing injured heart tissue.

So they can't use smartphones or WiFi, but bacteria have evolved some seriously complex strategies to communicate with one another. And the resulting interactions are a delicate balance of cooperation and, in some cases, ...

New research led by the UK's Centre for Ecology & Hydrology has revealed for the first time that flower-rich habitats are key to enhancing the survival of bumblebee families between years.

A discovery, several years in the making, by a University at Buffalo research team has proven that adult skin cells can be converted into neural crest cells (a type of stem cell) without any genetic modification, and that ...

The evolution of land animals has been shaped by barriers such as oceans and mountains which have divided them and sent them down different genetic paths.

(Phys.org)A trio of researchers with Anglia Ruskin University in the U.K. and the Australian National University has found that the male fiddler crab uses its oversized claw to get the attention of a prospective mate and ...

A 60-year-old mystery has been solved by biochemists at The University of Western Australia investigating the origin of a type of digestion-inhibiting proteins thought only to exist in two plant families that contain the ...

Please sign in to add a comment. Registration is free, and takes less than a minute. Read more

See the original post here:
Researchers decipher how the body controls stem cells - Phys.Org

Related Post


categoriaSkin Stem Cells commentoComments Off on Researchers decipher how the body controls stem cells – Phys.Org | dataMarch 15th, 2017

About...

This author published 5852 posts in this site.

Share

FacebookTwitterEmailWindows LiveTechnoratiDeliciousDiggStumbleponMyspaceLikedin

Comments are closed.





Personalized Gene Medicine | Mesenchymal Stem Cells | Stem Cell Treatment for Multiple Sclerosis | Stem Cell Treatments | Board Certified Stem Cell Doctors | Stem Cell Medicine | Personalized Stem Cells Therapy | Stem Cell Therapy TV | Individual Stem Cell Therapy | Stem Cell Therapy Updates | MD Supervised Stem Cell Therapy | IPS Stem Cell Org | IPS Stem Cell Net | Genetic Medicine | Gene Medicine | Longevity Medicine | Immortality Medicine | Nano Medicine | Gene Therapy MD | Individual Gene Therapy | Affordable Stem Cell Therapy | Affordable Stem Cells | Stem Cells Research | Stem Cell Breaking Research

Copyright :: 2024