Tag Archives: therapies for many common diseases

Stem cell news

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Oncogenes are generally thought to be genes that, when mutated, change healthy cells into cancerous tumor cells. Scientists at the Keck School of Medicine of the University of Southern California (USC) have proven that those genes also can change normal cells into stem-like cells, paving the way to a safer and more practical approach to treating diseases like multiple sclerosis and cancer with stem cell therapy.

“The reality may be more complicated than people think,” said Jiang F. Zhong, Ph.D., assistant professor of pathology at the Keck School. “What is a stem cell gene? What is a cancer gene? It may be the same thing.”

Zhong and colleagues at the Children’s Hospital of Orange County (CHOC) in California and Good Samaritan Hospital Medical Center in New York successfully converted human skin cells into brain cells by suppressing the expression of p53, a protein encoded by a widely studied oncogene. This suggests that p53 mutation helps determine cell fate — good or bad — rather than only the outcome of cancer.

The study is slated to appear in the online edition of Proceedings of the National Academy of Sciences, a peer-reviewed scientific journal, the week of July 18, 2011.

Stem cells

Stem cells

“When you turn off p53, people think the cell becomes cancerous because we tend to focus on the bad thing,” Zhong said. “Actually, the cell becomes more plastic and could do good things, too. Let’s say the cell is like a person who loses his job (the restriction of p53). He could become a criminal or he could find another job and have a positive effect on society. What pushes him one way or the other, we don’t know because the environment is very complicated.”

Stem cells can divide and differentiate into different types of cells in the body. In humans, embryonic stem cells differentiate into three families, or germ layers, of cells. The reasons why and how certain stem cells differentiate into particular layers are not clearly understood. However, from those layers, tissues and organs develop. The endoderm, for example, leads to formation of the stomach, colon and lungs, while the mesoderm forms blood, bone and heart tissue. In its study, Zhong’s team examined human skin cells, which are related to brain and neural cells from the ectoderm.


When p53 was suppressed, the skin cells developed into cells that looked exactly like human embryonic stem cells. But, unlike other human-made stem cells that are “pluripotent” and can become any other cells in the body, these cells differentiated only into cells from the same germ layer, ectoderm.

“IPSCs [induced pluripotent stem cells] can turn into anything, so they are hard to control,” Zhong said. “Our cells are staying within the ectoderm lineage.”

Zhong said he expects that suppressing other oncogenes in other families of cells would have the same effect, which could have critical significance for stem cell therapy. Future research should focus on determining which genes to manipulate, Zhong said.

This study was supported by the CHOC Children’s Foundation, CHOC Neuroscience Institute, Austin Ford Tribute Fund, W. M. Keck Foundation, National Institutes of Health and National Science Foundation.

New techniques to grow stem cells

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A new plastic surface which overcomes the difficulties associated with growing adult stem cells has been developed, according to scientists.

Standard surfaces have proved limited for growing large amounts and retaining the stem cells’ useful characteristics.

It is hoped the discovery could lead to the creation of stem cell therapies for re-growing bone and tissue, and also for conditions such as arthritis.

The study was carried out by Glasgow and Southampton universities.

The new “nano-patterned” surface was created using a manufacturing process similar to that used to make Blu-ray discs.

The surface is covered with tiny pits, which the researchers said made it more effective in allowing stem cells to grow and spread into useful cells for therapy.

Currently, when adult stem cells are harvested from a patient, they are then cultured in a laboratory to increase the quantities of cells and create a batch of sufficient volume to kick-start the process of cellular regeneration.

Stem cells

Stem cells

At this point they can be reintroduced back into the patient.

The process of culturing is made difficult because stem cells grown on standard plastic tissue culture surfaces do not always expand to create new stem cells but instead create other cells which are of no use in therapy.

Stem cell expansion can be boosted by immersing the cells in chemical solutions, but the scientists said these methods were limited in their effectiveness.

Dr Matthew Dalby, from the University of Glasgow, led the research alongside colleague Dr Nikolaj Gadegaard and Prof Richard Oreffo of the University of Southampton.


Mr Dalby said: “This new nano-structured surface can be used to very effectively culture mesencyhmal stem cells, taken from sources such as bone marrow, which can then be put to use in musculoskeletal, orthopaedic and connective tissues.

“If the same process can be used to culture other types of stem cells too – and this research is under way in our labs – our technology could be the first step on the road to developing large-scale stem cell culture factories, which would allow for the creation of a wide range of therapies for many common diseases such as diabetes, arthritis, Alzheimer’s disease and Parkinson’s disease.”

He said the group hoped to make the surface commercially available.

Prof Oreffo added: “It is important to realise the ability to retain skeletal stem cell phenotype using surface topography offers a step change in current approaches for stem cell biology.

“The implications for research and future interventions for patients with arthritis and other musculoskeletal diseases are substantial.”

The study was funded by the Biotechnology and Biological Sciences Research Council (BBSRC) and the University of Glasgow.

The paper, Nanoscale surfaces for the long-term maintenance of mesenchymalstem cell phenotype and multipotency, was published in the journal Nature Materials.