Archive for the ‘Skin Stem Cells’ Category

05/15/13Portland, Ore.

The breakthrough marks the first time human stem cells have been produced via nuclear transfer and follows several unsuccessful attempts by research groups worldwide

Scientists at Oregon Health & Science University and the Oregon National Primate Research Center (ONPRC) have successfully reprogrammed human skin cells to become embryonic stem cells capable of transforming into any other cell type in the body. It is believed that stem cell therapies hold the promise of replacing cells damaged through injury or illness. Diseases or conditions that might be treated through stem cell therapy include Parkinsons disease, multiple sclerosis, cardiac disease and spinal cord injuries.

The research breakthrough, led by Shoukhrat Mitalipov, Ph.D., a senior scientist at ONPRC, follows previous success in transforming monkey skin cells into embryonic stem cells in 2007. This latest research will be published in the journal Cell online May 15 and in print June 6.

The technique used by Drs. Mitalipov, Paula Amato, M.D., and their colleagues in OHSUs Division of Reproductive Endocrinology and Infertility, Department of Obstetrics & Gynecology, is a variation of a commonly used method called somatic cell nuclear transfer, or SCNT. It involves transplanting the nucleus of one cell, containing an individuals DNA, into an egg cell that has had its genetic material removed. The unfertilized egg cell then develops and eventually produces stem cells.

A thorough examination of the stem cells derived through this technique demonstrated their ability to convert just like normal embryonic stem cells, into several different cell types, including nerve cells, liver cells and heart cells. Furthermore, because these reprogrammed cells can be generated with nuclear genetic material from a patient, there is no concern of transplant rejection, explained Dr. Mitalipov. While there is much work to be done in developing safe and effective stem cell treatments, we believe this is a significant step forward in developing the cells that could be used in regenerative medicine.

Another noteworthy aspect of this research is that it does not involve the use of fertilized embryos, a topic that has been the source of a significant ethical debate.

The Mitalipov teams success in reprogramming human skin cells came through a series of studies in both human and monkey cells. Previous unsuccessful attempts by several labs showed that human egg cells appear to be more fragile than eggs from other species. Therefore, known reprogramming methods stalled before stem cells were produced.

To solve this problem, the OHSU group studied various alternative approaches first developed in monkey cells and then applied to human cells. Through moving findings between monkey cells and human cells, the researchers were able to develop a successful method.

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OHSU research team successfully converts human skin cells into ...

Induced pluripotent stem cells,[1] commonly abbreviated as iPS cells or iPSCs are a type of pluripotent stem cell artificially derived from a non-pluripotent cell typically an adult somatic cell by inducing a "forced" expression of specific genes.

Induced pluripotent stem cells are similar to natural pluripotent stem cells, such as embryonic stem (ES) cells, in many aspects, such as the expression of certain stem cell genes and proteins, chromatin methylation patterns, doubling time, embryoid body formation, teratoma formation, viable chimera formation, and potency and differentiability, but the full extent of their relation to natural pluripotent stem cells is still being assessed.[2] Induced pluripotent cells have been made from adult stomach, liver, skin cells, blood cells, prostate cells and urinary tract cells.[3]

iPSCs were first produced in 2006 from mouse cells and in 2007 from human cells in a series of experiments by Shinya Yamanaka's team at Kyoto University, Japan, and by James Thomson's team at the University of Wisconsin-Madison. For her iPSC research, Dr. Nancy Bachman, of Oneonta, NY, was awarded the Wolf Prize in Medicine in 2012 (along with John B. Gurdon).[4][5][6] For his iPSC discovery (and for deriving the first human embryonic stem cell), James Thomson received the 2011 Albany Medical Center Prize for Biomedical Research and the 2011 King Faisal International Prize, which he shared with Yamanaka. In October 2012, Yamanaka and fellow stem cell researcher John Gurdon were awarded the Nobel Prize in Physiology or Medicine "for the discovery that mature cells can be reprogrammed to become pluripotent."[7]

iPSCs are an important advance in stem cell research, as they may allow researchers to obtain pluripotent stem cells, which are important in research and potentially have therapeutic uses, without the controversial use of embryos. Because iPSCs are developed from a patient's own somatic cells, it was believed that treatment of iPSCs would avoid any immunogenic responses; however, Zhao et al. have challenged this assumption.[8]

Depending on the methods used, reprogramming of adult cells to obtain iPSCs may pose significant risks that could limit their use in humans. For example, if viruses are used to genomically alter the cells, the expression of cancer-causing genes "oncogenes" may potentially be triggered. In February 2008, scientists announced the discovery of a technique that could remove oncogenes after the induction of pluripotency, thereby increasing the potential use of iPS cells in human diseases.[9] In April 2009, it was demonstrated that generation of iPS cells is possible without any genetic alteration of the adult cell: a repeated treatment of the cells with certain proteins channeled into the cells via poly-arginine anchors was sufficient to induce pluripotency.[10] The acronym given for those iPSCs is piPSCs (protein-induced pluripotent stem cells).

Dedifferentiation to totipotency or pluripotency: an overview of methods. Various methods exist to revert adult somatic cells to pluripotency or totipotency. In the case of totipotency, reprogramming is mediated through a mature metaphase II oocyte as in somatic cell nuclear transfer (Wilmut et al., 1997). Recent work has demonstrated the feasibility of enucleated zygotes or early blastomeres chemically arrested during mitosis, such that nuclear envelope break down occurs, to support reprogramming to totipotency in a process called chromosome transfer (Egli and Eggan, 2010). Direct reprogramming methods support reversion to pluripotency; though, vehicles and biotypes vary considerably in efficiencies (Takahashi and Yamanaka, 2006). Viral-mediated transduction robustly supports dedifferentiation to pluripotency through retroviral or DNA-viral routes but carries the onus of insertional inactivation. Additionally, epigenetic reprogramming by enforced expression of OSKM through DNA routes exists such as plasmid DNA, minicircles, transposons, episomes and DNA mulicistronic construct targeting by homologous recombination has also been demonstrated; however, these methods suffer from the burden to potentially alter the recipient genome by gene insertion (Ho et al., 2010). While protein-mediated transduction supports reprogramming adult cells to pluripotency, the method is cumbersome and requires recombinant protein expression and purification expertise, and reprograms albeit at very low frequencies (Kim et al., 2009). A major obstacle of using RNA for reprogramming is its lability and that single-stranded RNA biotypes trigger innate antiviral defense pathways such as interferon and NF-B-dependent pathways. In vitro transcribed RNA, containing stabilizing modifications such as 5-methylguanosine capping or substituted ribonucleobases, e.g. pseudouracil, is 35-fold more efficient than viral transduction and has the additional benefit of not altering the somatic genome (Warren et al., 2010). An overarching goal of reprogramming methods is to replace genes with small molecules to assist in reprogramming. No cocktail has been identified to completely reprogram adult cells to totipotency or pluripotency, but many examples exist that improve the overall efficiency of the process and can supplant one or more genes by direct reprogramming routes (Feng et al., 2009; Zhu et al., 2010).

iPS cells are typically derived by transfection of certain stem cell-associated genes into non-pluripotent cells, such as adult fibroblasts, although this technique is becoming less popular since it is known to be prone to inducing cancer formation. Transfection is typically achieved through viral vectors, such as retroviruses. Transfected genes include the master transcriptional regulators Oct-3/4 (Pou5f1) and Sox2, although it is suggested that other genes enhance the efficiency of induction. After 34 weeks, small numbers of transfected cells begin to become morphologically and biochemically similar to pluripotent stem cells, and are typically isolated through morphological selection, doubling time, or through a reporter gene and antibiotic selection.

Induced pluripotent stem cells were first generated by Shinya Yamanaka's team at Kyoto University, Japan in 2006. Yamanaka used genes that had been identified as particularly important in embryonic stem cells (ESCs), and used retroviruses to transduce mouse fibroblasts with a selection of those genes. Eventually, four key pluripotency genes essential for the production of pluripotent stem cells were isolated; Oct-3/4, SOX2, c-Myc, and Klf4. Cells were isolated by antibiotic selection of Fbx15+ cells. However, this iPS cell line showed DNA methylation errors compared to original patterns in ESC lines and failed to produce viable chimeras if injected into developing embryos.

In June 2007, the same group published a breakthrough study along with two other independent research groups from Harvard, MIT, and the University of California, Los Angeles, showing successful reprogramming of mouse fibroblasts into iPS cells and even producing viable chimera. These cell lines were also derived from mouse fibroblasts by retroviral mediated reactivation of the same four endogenous pluripotent factors, but the researchers now selected a different marker for detection. Instead of Fbx15, they used Nanog which is an important gene in ESCs. DNA methylation patterns and production of viable chimeras (and thereby contributing to subsequent germ-line production) indicated that Nanog is a major determinant of cellular pluripotency.[11][12][13][14][15]

Unfortunately, two of the four genes used (namely, c-Myc and KLF4) are oncogenic, and 20% of the chimeric mice developed cancer. In a later study, Yamanaka reported that one can create iPSCs even without c-Myc. The process takes longer and is not as efficient, but the resulting chimeras didn't develop cancer.[16]

Link:
Induced pluripotent stem cell - Wikipedia, the free encyclopedia

By Jeanette Jacknin M.D.

Dr Jacknin will be speaking about Cosmaceuticals at the upcoming 17th World Congress on Anti-Aging and Regenerative Medicine in Orlando, Florida, April 23-25, 2009.

Stem cells have recently become a huge buzzword in the skincare world. But what does this really mean? Skincare specialists are not using embryonic stem cells; it is impossible to incorporate live materials into a skincare product. Instead, companies are creating products with specialized peptides and enzymes or plant stem cells which, when applied topically on the surface, help protect the human skin stem cells from damage and deterioration or stimulate the skin's own stem cells. National Stem Cell was one of the few companies who actually incorporated into their skin care an enzyme secreted from human embryonic stem cells, but they are in the process of switching over to use non-embryonic stem cells from which to take the beneficial enzyme.

Stem cells have the remarkable potential to develop into many different cell types in the body. When a stem cell divides, it can remain a stem cell or become another type of cell with a more specialized function, such as a skin cell. There are two types of stem cells, embryonic and adult.

Embryonic stem cells are exogenous in that they are harvested from outside sources, namely, fertilized human eggs. Once harvested, these pluripotent stem cells are grown in cell cultures and manipulated to generate specific cell types so they can be used to treat injury or disease.

Unlike embryonic stem cells, adult or multipotent stem cells are endogenous. They are present within our bodies and serve to maintain and repair the tissues in which they are found. Adult stem cells are found in many organs and tissues, including the skin. In fact, human skin is the largest repository of adult stem cells in the body. Skin stem cells reside in the basal layer of the epidermis where they remain dormant until they are activated by tissue injury or disease. 1

There is controversy surrounding the use of stem cells, as some experts say that any product that claims to affect the growth of stem cells or the replication process is potentially dangerous, as it may lead to out-of-control replication or mutation. Others object to using embryonic stem cells from an ethical point of view. Some researchers believe that the use of stem cell technology for a topical, anti-aging cosmetic trivializes other, more important medical research in this field.

The skin stem cells are found near hair follicles and sweat glands and lie dormant until they "receive" signals from the body to begin the repair mode. In skincare, the use of topical products stimulates the stem cell to split into two types of cells: a new, similar stem cell and a "daughter" cell, which is able to create almost every kind of new cell in a specialized system. This means that the stem cell can receive the message to create proteins, carbohydrates and lipids to help repair fine lines, wrinkles and restore and maintain firmness and elasticity.1

First to the market in Britain in April 2007 and the U.S. was ReVive's Peau Magnifique, priced at a staggering 1,050. Manufacturers claim it uses an enzyme called telomerase to "convert resting adult stem cells to newly-minted skin cells' and 'effectively resets your skin's "ageing clock" by a minimum of five years'. The product claims long-term use 'will result in a generation of new skin cells, firmer skin with a 45 per cent reduction in wrinkles and increased long-term skin clarity'. Peau Magnifique is the latest in a line of products developed by Dr Gregory Bays Brown, a former plastic surgeon.

In the course of his research into healing burns victims, Dr Brown discovered a substance called Epidermal Growth Factor (EGF) that is released in the body when there is an injury, and, when applied to burns or wounds, dramatically accelerates the healing process. He believed the same molecule could be used to regenerate ageing skin and went on to develop ReVive, a skincare range based around it. 2

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Stem cells in skin care...What does it really mean? | Worldhealth ...

Public release date: 10-Oct-2013 [ | E-mail | Share ]

Contact: Mary Beth O'Leary moleary@cell.com 617-397-2802 Cell Press

Human skin must cope with UV radiation from the sun and other harmful environmental factors that fluctuate in a circadian manner. A study published by Cell Press on October 10th in the journal Cell Stem Cell has revealed that human skin stem cells deal with these cyclical threats by carrying out different functions depending on the time of day. By activating genes involved in UV protection during the day, these cells protect themselves against radiation-induced DNA damage. The findings could pave the way for new strategies to prevent premature aging and cancer in humans.

"Our study shows that human skin stem cells posses an internal clock that allows them to very accurately know the time of day and helps them know when it is best to perform the correct function," says study author Salvador Aznar Benitah an ICREA Research Professor who developed this project at the Centre for Genomic Regulation (CRG, Barcelona), and who has recently moved his lab to the Institute for Research in Biomedicine (IRB Barcelona). "This is important because it seems that tissues need an accurate internal clock to remain healthy."

A variety of cells in our body have internal clocks that help them perform certain functions depending on the time of day, and skin cells as well as some stem cells exhibit circadian behaviors. Benitah and his collaborators previously found that animals lacking normal circadian rhythms in skin stem cells age prematurely, suggesting that these cyclical patterns can protect against cellular damage. But until now, it has not been clear how circadian rhythms affect the functions of human skin stem cells.

To address this question, Benitah teamed up with his collaborators Luis Serrano and Ben Lehner of the Centre for Genomic Regulation. They found that distinct sets of genes in human skin stem cells show peak activity at different times of day. Genes involved in UV protection become most active during the daytime to guard these cells while they proliferatethat is, when they duplicate their DNA and are more susceptible to radiation-induced damage.

"We know that the clock is gradually disrupted in aged mice and humans, and we know that preventing stem cells from accurately knowing the time of the day reduces their regenerative capacity," Benitah says. "Our current efforts lie in trying to identify the causes underlying the disruption of the clock of human skin stem cells and hopefully find means to prevent or delay it."

###

Cell Stem Cell, Janich et al.: "Human epidermal stem cell function is regulated by circadian oscillations."

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Circadian rhythms in skin stem cells protect us against UV rays

Can New Bone Be Made From Skin Stem Cells?
Cartilage can be made from skin stem cells and now bone! In this video, Sharecare expert Michael Roizen, MD, chief wellness officer for Cleveland Clinic, exp...

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Can New Bone Be Made From Skin Stem Cells? - Video

Skin stem cells hold promise for burn patients
Vincent Gabriel, MD Jeff Biernaskie, PhD Recipients of Alberta Innovates - Health Solutions Collaborative Research Innovation Opportunities program

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Skin stem cells hold promise for burn patients - Video

Dec. 27, 2012 Researchers have uncovered a novel role of BRCA1 in regulating the survival of skin stem cells.

Our DNA, which stores our genetic information, is constantly submitted to damage. If not properly repaired, DNA damage can lead to cell death, which may in turn lead to tissue exhaustion and aging, or induce mutations resulting in uncontrolled cell proliferation and cancer. Brca1 is a key gene that mediates DNA repair. Mutations in Brca1 lead to familial and sporadic breast and ovarian cancer in humans.

In this study published in Genes and Development, researchers led by Cdric Blanpain, MD/PhD, Professor at Universit libre de Bruxelles (ULB) and WELBIO investigator, showed the critical role of Brca1 for the maintenance of hair follicle stem cells.

Peggy Sotiropoulou and colleagues showed that upon deletion of the breast cancer associated gene Brca1 in the epidermis, hair follicle cells show high levels of DNA damage and cell death, which induce hyperproliferation and finally exhaustion of hair follicle stem cells resulting in hair follicle degeneration. In contrast, the other types of stem cells located in the epidermis, which are forming the skin barrier and the sebaceous glands, are maintained and continue to function normally despite the absence of BRCA1, demonstrating the different requirement for BRCA1 in the distinct types of adult stem cells. "We were very surprised to see that distinct types of cells residing within the same tissue may exhibit such profoundly different responses to the deletion of the same, crucial gene for DNA repair gene" comments Peggy Sotiropoulou, the first author of this study.

This work is very important to understand the DNA repair mechanisms in different types of adult stem cells and at different stages of their activation. If other stem cells of the body also require BRCA1 for their survival, this result may potentially explain why Brca1 mutations in women lead preferentially to the development of only breast and ovarian cancers.

This work was supported by the FNRS, WELBIO, the program d'excellence CIBLES of Wallonia, a research grant from the Fondation Contre le Cancer, the Fondation ULB, the Fonds Yvonne Bol, and the Fonds Gaston Ithier, a starting grant of the European Research Council (ERC) and the EMBO Young Investigator Program.

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The above story is reprinted from materials provided by Libre de Bruxelles, Universit, via AlphaGalileo.

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Novel role of BRCA1 in regulating the survival of skin stem cells identified

DermaStem - An all natural skincare serum based on StemCells science
Independent clinical trials show DRAMATIC results - 25% fewer wrinkles,30% more moisture and 10% more elasticity...in just 28 days! Dermastem is a breakthrough serum revitalizes the skin at the cellular level, to restore and maintain the skin #39;s youthful vibrance. This serum is a concentrate fusion of natural oils that blends invisibly into the skin. This all-natural serum contains a velvety emulsion of the world #39;s most restorative ingredients. This revolutionary product works to reduce the signs of premature aging by supporting the work of skin stem cells, the natural renewal system of the skin. To order online or more information,please contact us at http://www.jainaz.stemtechbiz.com or email to rizalnazrul@gmail.com You may also call Rizal at +60 13 620 6203 / Nazrul at +60 19 360 1032From:rizal yasin a.k.a jaiViews:5 0ratingsTime:06:49More inScience Technology

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DermaStem - An all natural skincare serum based on StemCells science - Video

An all natural skincare serum based on stemcells science
Independent clinical trials show DRAMATIC results - 25% fewer wrinkles,30% more moisture and 10% more elasticity...in just 28 days! Our breakthrough serum revitalizes the skin at the cellular level, to restore and maintain the skin #39;s youthful vibrance. DermaStem is a mocha-hued fusion of natural oils that blends invisibly into the skin. This all-natural serum contains a velvety emulsion of the world #39;s most restorative ingredients. This revolutionary product works to reduce the signs of premature aging by supporting the work of skin stem cells, the natural renewal system of the skin. For order online or more information,please contact us at http://www.myonline.stemtechbiz.com or email to fusioncreations@gmail.com.From:Tony Lim Careen SeeViews:1 0ratingsTime:06:48More inHowto Style

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An all natural skincare serum based on stemcells science - Video

ANAHEIM, Calif., Nov. 13, 2012 /PRNewswire/ --A step ahead of the colossal skincare market, Ageless Derma, an innovative, anti-aging skincare company, leads its competition as the first to integrate the latest technology, PhytoCellTec. This cutting-edge technology cultivates stem cells from a rare apple and when incorporated into the Ageless Derma Stem Cell and Peptide Anti-Wrinkle cream, has proven to diminish wrinkles with exceptional results.

Patent pending, PhytoCellTec Malus Domestica is a liposomal preparation of apple stem cells designed to protect skin stem cells. Known for minimal shriveling and extended longevity, the Uttwiler Spalauber apple is rich in proteins, phytonutrients, and long-living cells. PhytoCellTec Malus Domestica is a scientifically proven breakthrough that effectively combats skin aging.

"We were excited to find new, revolutionary stem cell technology," said Dr. Farid Mostamand, owner and founder of the Ageless Derma skincare line. "This extraordinary process is a leap forward. Our customers want non-surgical options to fight wrinkles and sagging skin and PhytoCellTec technology provides exactly that. This has produced remarkable results for eliminating wrinkles so we integrated it into our Ageless Derma anti-wrinkle cream."

Pioneered by Mibelle BioChemistry Group, the founding company hosts scientific studies to substantiate claims that PhytoCellTec Malus Domestica provides revolutionary skin rejuvenation. Honored with the BSB Innovation Award in 2008 for best ingredient, Mibelle BioChemistry Group developed PhytoCellTec technology to enable plant stem cells to grow in considerable numbers. In comprehensive studies the company was able to prove PhytoCellTecMalus Domestica, the dynamic ingredient derived from the apple stem cells, supports longevity and vitality of skin stem cells.

In a study of volunteers ranging in age from 37 to 64, 100% of the subjects showed significant decreases in wrinkle depth. The volunteers applied a concentration of 2% PhytoCellTec Malus Domestica twice daily for 28 days to "crow's feet," or wrinkles near the eyes, to diminish wrinkles.

PhytoCellTec enables the cultivation of stem cells by using the same repair methods plant cells use. The PhytoCellTec process selects a diminutive piece of plant material which is then damaged to result in callus formation. The formations are incubated and harvested in order to obtain stem cells.

"Along with this miraculous stem cell factor, our anti-aging creams have other effective, safe ingredients such as vitamins, minerals, and peptides. Peptides also play a big role in our anti-wrinkle creams as they stimulate collagen growth to keep skin looking young," said Dr. Mostamand.

About Ageless Derma:

Ageless Derma is accredited with the Better Business Bureau and offers a 30-day money-back guarantee. Ageless Derma products are available at Focus Medical Spa in Anaheim, CA, through the website http://www.agelessderma.com, or toll-free (877) 777-1940. For more information on Ageless Derma, please contact Dr. Farid Mostamand at mostamand5@gmail.com or call (877) 777-1940.

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Ageless Derma Formulates Apple Stem Cells into Anti-Wrinkle Cream with PhytoCellTec Technology

La Prairie Cellular Power Infusion
Recharge your cell energy at the source cellular A never before cell energizer propels your skin toward agelessness. Skin stem cells awaken. Regeneration accelerates. power Supports the cellular power-stations in your cells, allowing them to go into hyper-drive to fuel the cellular-renewal process. A power-surge floods your skin with renewal aliveness. infusion Working from the inside our, your skin tissue is restored with new structure and elasticity. Vibrancy re-ignites... lamination glows... texture silkens. Youthful, moist, firmed resiliency meets your delighted touch.From:TANGSSingaporeViews:425 1ratingsTime:02:47More inHowto Style

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Skin Doctors YouthCell
YouthCell contains the latest plant stem cell technology (PhytoCellTec trade;) to help delay the appearance of chronological ageing of the skin. These plant stem cells are sourced from a rare, long-living swiss apple which has the unique ability to regenerate its cells once it falls from the tree. It is this characteristic, that when used on the skin, promotes the longevity of skin cells. YouthCell turns on the switch that tells your own skin stem cells to start producing again. Targeting the skin renewal process with Skin Doctors YouthCell Youth Activating Cream means younger, rejuvenated, more beautiful looking skin. Skin Doctors YouthCell is available at feelunique.comFrom:feeluniquetvViews:1077 0ratingsTime:00:31More inHowto Style

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Skin Doctors YouthCell - Video

La Prairie Cellular Power Infusion
Recharge your cell energy at the source cellular A never before cell energizer propels your skin toward agelessness. Skin stem cells awaken. Regeneration accelerates. power Supports the cellular power-stations in your cells, allowing them to go into hyper-drive to fuel the cellular-renewal process. A power-surge floods your skin with renewal aliveness. infusion Working from the inside our, your skin tissue is restored with new structure and elasticity. Vibrancy re-ignites... lamination glows... texture silkens. Youthful, moist, firmed resiliency meets your delighted touch.From:TANGSSingaporeViews:425 1ratingsTime:02:47More inHowto Style

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La Prairie Cellular Power Infusion - Video

The nuclei of brain stem cells in some Parkinson's patients become misshapen with age. The discovery opens up new ways to target the disease.

Nubby nucleus: Brain cells from a deceased Parkinsons patient have deformed nuclei (bottom) compared with normal brain cells from an individual of a similar age. Merce Marti and Juan Carlos Izpisua Belmonte

Stem cells in the brains of some Parkinson's patients are increasingly damaged as they age, an effect that eventually diminishes their ability to replicate and differentiate into mature cell types. Researchers studied neural stem cells created from patients' own skin cells to identify the defects. The findings offer a new focus for therapeutics that target the cellular change.

The report, published today in Nature, takes advantage of the ability to model diseases in cell culture by turning patient's own cells first into so-called induced pluripotent stem cells and then into disease-relevant cell typesin this case, neural stem cells. The basis of these techniques was recognized with a Nobel Prize in medicine last week.

The authors studied cells taken from patients with a heritable form of Parkinson's that stems from mutations in a gene. After growing several generation of neural stem cells derived from patients with that mutation, they saw the cell nuclei start to develop abnormal shapes. Those abnormalities compromise the survival of the neural stem cells, says study coauthor Ignacio Sancho-Martinez of the Salk Institute for Biological Studies in La Jolla, California.

Today's study "brings to light a new avenue for trying to figure out the mechanism of Parkinson's," says Scott Noggle of the New York Stem Cell Foundation. It also provides a new set of therapeutic targets: "Drugs that target or modify the activity [of the gene] could be applicable to Parkinson's patients. This gives you a handle on what to start designing drug screens around."

The strange nuclei were also seen in patients who did not have a known genetic basis for Parkinson's disease. The authors suggest this indicates that dysfunctional neural stem cells could contribute to Parkinson's. While that conclusion is "highly speculative," says Ole Isacson, a neuroscientist at Harvard Medical School, the study demonstrates the "wealth of data and information that we now can gain from iPS cells."

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Parkinson's cells

The nuclei of brain stem cells in some Parkinson's patients become misshapen with age. The discovery opens up new ways to target the disease.

Nubby nucleus: Brain cells from a deceased Parkinsons patient have deformed nuclei (bottom) compared with normal brain cells from an individual of a similar age. Merce Marti and Juan Carlos Izpisua Belmonte

Stem cells in the brains of some Parkinson's patients are increasingly damaged as they age, an effect that eventually diminishes their ability to replicate and differentiate into mature cell types. Researchers studied neural stem cells created from patients' own skin cells to identify the defects. The findings offer a new focus for therapeutics that target the cellular change.

The report, published today in Nature, takes advantage of the ability to model diseases in cell culture by turning patient's own cells first into so-called induced pluripotent stem cells and then into disease-relevant cell typesin this case, neural stem cells. The basis of these techniques was recognized with a Nobel Prize in medicine last week.

The authors studied cells taken from patients with a heritable form of Parkinson's that stems from mutations in a gene. After growing several generation of neural stem cells derived from patients with that mutation, they saw the cell nuclei start to develop abnormal shapes. Those abnormalities compromise the survival of the neural stem cells, says study coauthor Ignacio Sancho-Martinez of the Salk Institute for Biological Studies in La Jolla, California.

Today's study "brings to light a new avenue for trying to figure out the mechanism of Parkinson's," says Scott Noggle of the New York Stem Cell Foundation. It also provides a new set of therapeutic targets: "Drugs that target or modify the activity [of the gene] could be applicable to Parkinson's patients. This gives you a handle on what to start designing drug screens around."

The strange nuclei were also seen in patients who did not have a known genetic basis for Parkinson's disease. The authors suggest this indicates that dysfunctional neural stem cells could contribute to Parkinson's. While that conclusion is "highly speculative," says Ole Isacson, a neuroscientist at Harvard Medical School, the study demonstrates the "wealth of data and information that we now can gain from iPS cells."

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Stem Cells Reveal Defect in Parkinson's Cells

By Charles Choi, LiveScience contributor

Death will come for us all one day, but life will not fade from our bodies all at once. After our lungs stop breathing, our hearts stop beating, our minds stop racing, our bodies cool, and long after our vital signs cease, little pockets of cells can live for days, even weeks. Now scientists have harvested such cells from the scalps and brain linings of human corpses and reprogrammed them into stem cells.

In other words, dead people can yield living cells that can be converted into any cell or tissue in the body.

As such, this work could help lead to novel stem cell therapies and shed light on a variety of mental disorders, such as schizophrenia, autism and bipolar disorder, which may stem from problems with development, researchers say.

Making stem cells Mature cells can be made or induced to become immature cells, known as pluripotent stem cells, which have the ability to become any tissue in the body and potentially can replace cells destroyed by disease or injury. This discovery was honored last week with the Nobel Prize.

Past research showed this same process could be carried out with so-called fibroblasts taken from the skin of human cadavers. Fibroblasts are the most common cells of connective tissue in animals, and they synthesize the extracellular matrix, the complex scaffolding between cells. [ Science of Death: 10 Tales from the Crypt ]

Cadaver-collected fibroblasts can be reprogrammed into induced pluripotent stem cells using chemicals known as growth factors that are linked with stem cell activity. Reprogrammed cells could then develop into a multitude of cell types, including the neurons found in the brain and spinal cord. However, bacteria and fungi on the skin can wreak havoc on the culturing processes used to grow cells in labs, making the process tricky to successfully carry out.

Now scientists have taken fibroblasts from the scalps and the brain linings of 146 human brain donors and grown induced pluripotent stem cells from them as well.

"We were able to culture living cells from deceased individuals on a larger scale than ever done before," researcher Thomas Hyde, a neuroscientist, neurologist and chief operating officer at the Lieber Institute for Brain Development in Baltimore, told LiveScience. Previous studies had only grown fibroblasts from a total of about a half-dozen cadavers.

The bodies had been dead up to nearly two days before scientists collected tissues from them. The corpses had been kept cool in the morgue, but not frozen.

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New life for the dead: Stem cells from corpse scalp

Death will come for us all one day, but life will not fade from our bodies all at once. After our lungs stop breathing, our hearts stop beating, our minds stop racing, our bodies cool, and long after our vital signs cease, little pockets of cells can live for days, even weeks. Now scientists have harvested such cells from the scalps and brain linings of human corpses and reprogrammed them into stem cells.

In other words, dead people can yield living cells that can be converted into any cell or tissue in the body.

As such, this work could help lead to novel stem cell therapies and shed light on a variety of mental disorders, such as schizophrenia, autism and bipolar disorder, which may stem from problems with development, researchers say.

Making stem cells

Mature cells can be made or induced to become immature cells, known as pluripotent stem cells, which have the ability to become any tissue in the body and potentially can replace cells destroyed by disease or injury. This discovery was honored last week with the Nobel Prize.

Past research showed this same process could be carried out with so-called fibroblasts taken from the skin of human cadavers. Fibroblasts are the most common cells of connective tissue in animals, and they synthesize the extracellular matrix, the complex scaffolding between cells. [Science of Death: 10 Tales from the Crypt]

Cadaver-collected fibroblasts can be reprogrammed into induced pluripotent stem cells using chemicals known as growth factors that are linked with stem cell activity. Reprogrammed cells could then develop into a multitude of cell types, including the neurons found in the brain and spinal cord. However, bacteria and fungi on the skin can wreak havoc on the culturing processes used to grow cells in labs, making the process tricky to successfully carry out.

Now scientists have taken fibroblasts from the scalps and the brain linings of 146 human brain donors and grown induced pluripotent stem cells from them as well.

"We were able to culture living cells from deceased individuals on a larger scale than ever done before," researcher Thomas Hyde, a neuroscientist, neurologist and chief operating officer at the Lieber Institute for Brain Development in Baltimore, told LiveScience. Previous studies had only grown fibroblasts from a total of about a half-dozen cadavers.

The bodies had been dead up to nearly two days before scientists collected tissues from them. The corpses had been kept cool in the morgue, but not frozen.

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Human Cadaver Brains May Provide New Stem Cells

Public release date: 15-Oct-2012 [ | E-mail | Share ]

Contact: Karen Robinson karobinson@som.umaryland.edu 410-706-7590 University of Maryland Medical Center

A new method of using adult stem cells as a model for the hereditary condition Gaucher disease could help accelerate the discovery of new, more effective therapies for this and other conditions such as Parkinson's, according to new research from the University of Maryland School of Medicine.

Scientists at the University of Maryland School of Medicine reprogrammed stem cells to develop into cells that are genetically similar to and react to drugs in a similar way as cells from patients with Gaucher disease. The stem cells will allow the scientists to test potential new therapies in a dish, accelerating the process toward drug discovery, according to the paper published online in the journal the Proceedings of the National Academy of Sciences (PNAS) on Oct. 15 (Panicker et.al.).

The study was funded with $1.7 million in grants from the Maryland Stem Cell Research Fund; researchers received a start-up grant for $200,000 in 2007 and a larger, five-year grant for $1.5 million in 2009.

"We have created a model for all three types of Gaucher disease, and used stem cell-based tests to evaluate the effectiveness of therapies," says senior author Ricardo Feldman, Ph.D., associate professor of microbiology and immunology at the University of Maryland School of Medicine, and a research scientist at the University of Maryland Center for Stem Cell Biology and Regenerative Medicine. "We are confident that this will allow us to test more drugs faster, more accurately and more safely, bringing us closer to new treatments for patients suffering from Gaucher disease. Our findings have potential to help patients with other neurodegenerative diseases as well. For example, about 10 percent of Parkinson's disease patients carry mutations in the recessive gene for Gaucher disease, making our research possibly significant for Parkinson's disease as well."

Gaucher disease is the most frequent lipid-storage disease. It affects 1 in 50,000 people in the general population. It is most common in Ashkenazi Jews, affecting 1 in 1,000 among that specific population. The disease occurs in three subtypes Type 1 is the mildest and most common form of the disease, causing symptoms such as enlarged livers and spleens, anemia and bone disease. Type 2 causes very serious brain abnormalities and is usually fatal before the age of two, while Type 3 affects children and adolescents.

The condition is a recessive genetic disorder, meaning that both parents must be carriers for a child to suffer from Gaucher. However, said Dr. Feldman, studies have found that people with only one copy of a mutated Gaucher gene those known as carriers are at an increased risk of developing Parkinson's disease.

"This science is a reflection of the mission of the University of Maryland School of Medicine to take new treatments from bench to bedside, from the laboratory to patients, as quickly as possible," says E. Albert Reece, M.D., Ph.D., M.B.A., vice president for medical affairs at the University of Maryland and John Z. and Akiko K. Bowers Distinguished Professor and dean of the University of Maryland School of Medicine. "We are excited to see where this research goes next, bringing new hope to Gaucher patients and their families."

Dr. Feldman and his colleagues used the new reprogramming technology developed by Shinja Yamanaka in Japan, who was recognized with this year's Nobel Prize for Medicine or Physiology. Scientists engineered cells taken from the skin of Gaucher patients, creating human induced pluripotent stem cells, known as hiPSC stem cells that are theoretically capable of forming any type of cell in the body. Scientists differentiated the cells to form white blood cells known as macrophages and neuronal cells.

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University of Maryland School of Medicine scientists develop stem cell model for hereditary disease

ScienceDaily (Oct. 15, 2012) A new method of using adult stem cells as a model for the hereditary condition Gaucher disease could help accelerate the discovery of new, more effective therapies for this and other conditions such as Parkinson's, according to new research from the University of Maryland School of Medicine.

Scientists at the University of Maryland School of Medicine reprogrammed stem cells to develop into cells that are genetically similar to and react to drugs in a similar way as cells from patients with Gaucher disease. The stem cells will allow the scientists to test potential new therapies in a dish, accelerating the process toward drug discovery, according to the paper published online in the journal the Proceedings of the National Academy of Sciences (PNAS) on Oct. 15.

"We have created a model for all three types of Gaucher disease, and used stem cell-based tests to evaluate the effectiveness of therapies," says senior author Ricardo Feldman, Ph.D., associate professor of microbiology and immunology at the University of Maryland School of Medicine, and a research scientist at the University of Maryland Center for Stem Cell Biology and Regenerative Medicine. "We are confident that this will allow us to test more drugs faster, more accurately and more safely, bringing us closer to new treatments for patients suffering from Gaucher disease. Our findings have potential to help patients with other neurodegenerative diseases as well. For example, about 10 percent of Parkinson's disease patients carry mutations in the recessive gene for Gaucher disease, making our research possibly significant for Parkinson's disease as well."

Gaucher disease is the most frequent lipid-storage disease. It affects 1 in 50,000 people in the general population. It is most common in Ashkenazi Jews, affecting 1 in 1,000 among that specific population. The disease occurs in three subtypes -- Type 1 is the mildest and most common form of the disease, causing symptoms such as enlarged livers and spleens, anemia and bone disease. Type 2 causes very serious brain abnormalities and is usually fatal before the age of two, while Type 3 affects children and adolescents.

The condition is a recessive genetic disorder, meaning that both parents must be carriers for a child to suffer from Gaucher. However, said Dr. Feldman, studies have found that people with only one copy of a mutated Gaucher gene -- those known as carriers -- are at an increased risk of developing Parkinson's disease.

"This science is a reflection of the mission of the University of Maryland School of Medicine -- to take new treatments from bench to bedside, from the laboratory to patients, as quickly as possible," says E. Albert Reece, M.D., Ph.D., M.B.A., vice president for medical affairs at the University of Maryland and John Z. and Akiko K. Bowers Distinguished Professor and dean of the University of Maryland School of Medicine. "We are excited to see where this research goes next, bringing new hope to Gaucher patients and their families."

Dr. Feldman and his colleagues used the new reprogramming technology developed by Shinja Yamanaka in Japan, who was recognized with this year's Nobel Prize for Medicine or Physiology. Scientists engineered cells taken from the skin of Gaucher patients, creating human induced pluripotent stem cells, known as hiPSC -- stem cells that are theoretically capable of forming any type of cell in the body. Scientists differentiated the cells to form white blood cells known as macrophages and neuronal cells.

A key function of macrophages in the body is to ingest and eliminate damaged or aged red blood cells. In Gaucher disease, the macrophages are unable to do so -- they can't digest a lipid present in the red blood cell membrane. The macrophages become engorged with lipid and cannot completely clear the ingested red blood cells. This results in blockage of membrane transport pathways in the macrophages lodged in the bone marrow, spleen and liver. The macrophages that the scientists created from the reprogrammed stem cells exhibited this characteristic hallmark of the macrophages taken from Gaucher patients.

To further test the stem cells, the scientists administered a recombinant enzyme that is effective in treating Gaucher patients with Type 1 disease. When the cells were treated with the enzyme, the function of the macrophages was restored -- they completely cleared the red blood cells.

"The creation of these stem cell lines is a lovely piece of stem cell research," said Curt Civin, M.D., professor of pediatrics and physiology, associate dean for research and founding director of the Center for Stem Cell Biology & Regenerative Medicine at the University of Maryland School of Medicine. "Dr. Feldman is already using these Gaucher patient-derived macrophages to better understand the disease fundamentals and to find novel medicines for Gaucher disease treatment. A major goal of our Center for Stem Cell Biology & Regenerative Medicine is to translate our fundamental discoveries into innovative and practical clinical applications that will enhance the understanding, diagnosis, treatment, and prevention of many human diseases. Clinical applications include not only transplantation of stem cells, but also the use of stem cells for drug discovery as Dr. Feldman's studies so beautifully illustrate."

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Stem cell model for hereditary disease developed

Washington, October 13 (ANI): In a new study, researchers have taken the first steps to create neural-like stem cells from muscle tissue in animals.

"Reversing brain degeneration and trauma lesions will depend on cell therapy, but we can't harvest neural stem cells from the brain or spinal cord without harming the donor," Osvaldo Delbono, lead author of the study from Wake Forest Baptist Medical Center, said.

"Skeletal muscle tissue, which makes up 50 percent of the body, is easily accessible and biopsies of muscle are relatively harmless to the donor, so we think it may be an alternative source of neural-like cells that potentially could be used to treat brain or spinal cord injury, neurodegenerative disorders, brain tumours and other diseases, although more studies are needed," Delbono said.

In an earlier study, the Wake Forest Baptist team isolated neural precursor cells derived from skeletal muscle of adult transgenic mice.

In the current research, the team isolated neural precursor cells from in vitro adult skeletal muscle of various species including non-human primates and aging mice, and showed that these cells not only survived in the brain, but also migrated to the area of the brain where neural stem cells originate.

Another issue the researchers investigated was whether these neural-like cells would form tumours, a characteristic of many types of stem cells. To test this, the team injected the cells below the skin and in the brains of mice, and after one month, no tumours were found.

"Right now, patients with glioblastomas or other brain tumours have very poor outcomes and relatively few treatment options," Alexander Birbrair, first author of the study, said.

"Because our cells survived and migrated in the brain, we may be able to use them as drug-delivery vehicles in the future, not only for brain tumours but also for other central nervous system diseases," he added.

The findings of the study have been published online in the journals Experimental Cell Research and Stem Cell Research. ANI)

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Stem cells from muscle tissue 'may help cure neurodegenerative diseases'

By Mary Brophy Marcus HealthDay Reporter

FRIDAY, Oct. 12 (HealthDay News) -- Autism researchers have been given the go-ahead by the U.S. Food and Drug Administration to launch a small study in children with autism that evaluates whether a child's own umbilical cord blood may be an effective treatment.

Thirty children with the disorder, aged 2 to 7, will receive injections of their own stem cells from umbilical cord blood banked by their parents after their births. All of the cord blood comes from the Cord Blood Registry, the world's largest stem cell bank.

Scientists at Sutter Neuroscience Institute, in Sacramento, Calif., said the placebo-controlled study will evaluate whether the stem cell therapy helps improve language and behavior in the youngsters.

There is anecdotal evidence that stem cell infusions may have a benefit in other conditions such as cerebral palsy, said lead study investigator Dr. Michael Chez, director of pediatric neurology at the institute.

"We're hoping we'll see in the autism population a group of patients that also responds," Chez said. Other autism and stem cell research is going on abroad, but this study is the first to use a child's own cord blood stem cells.

Chez said the study will involve only patients whose autism is not linked to a genetic syndrome or brain injury, and all of the children will eventually receive the stem cells.

Two infusions will take place during the 13-month study. At the start of the research, the children will be split into two groups, half receiving an infusion of cord blood stem cells and half receiving a placebo. At six months, the groups will swap therapies. The infusions will be conducted on an outpatient basis with close monitoring, Chez said.

"We're working with Sutter Children's Hospital, who does our oncology infusions with the same-age children," he said. "They are very experienced nurses who work with preschool and school-age kids to help them get through medical experiences."

Each child and his or her parents will be given a private room with a television and videos, beverages, and perhaps a visit from the hospital's canine therapy dog, and then a topical anesthetic will be applied to the arm to numb the skin before intravenous needle placement. A hematology expert will be giving the infusions and monitoring for safety, said Chez, who noted that each child will be watched closely for an hour and a half before heading home. They will be seen the next day as well for a safety check.

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Could Stem Cells Treat Autism? Newly Approved Study May Tell

ScienceDaily (Oct. 12, 2012) Scientists at Wake Forest Baptist Medical Center have taken the first steps to create neural-like stem cells from muscle tissue in animals.

Details of the work are published in two complementary studies published in the September online issues of the journals Experimental Cell Research and Stem Cell Research.

"Reversing brain degeneration and trauma lesions will depend on cell therapy, but we can't harvest neural stem cells from the brain or spinal cord without harming the donor," said Osvaldo Delbono, M.D., Ph.D., professor of internal medicine at Wake Forest Baptist and lead author of the studies.

"Skeletal muscle tissue, which makes up 50 percent of the body, is easily accessible and biopsies of muscle are relatively harmless to the donor, so we think it may be an alternative source of neural-like cells that potentially could be used to treat brain or spinal cord injury, neurodegenerative disorders, brain tumors and other diseases, although more studies are needed."

In an earlier study, the Wake Forest Baptist team isolated neural precursor cells derived from skeletal muscle of adult transgenic mice (PLOS ONE, Feb. 3, 2011).

In the current research, the team isolated neural precursor cells from in vitro adult skeletal muscle of various species including non-human primates and aging mice, and showed that these cells not only survived in the brain, but also migrated to the area of the brain where neural stem cells originate.

Another issue the researchers investigated was whether these neural-like cells would form tumors, a characteristic of many types of stem cells. To test this, the team injected the cells below the skin and in the brains of mice, and after one month, no tumors were found.

"Right now, patients with glioblastomas or other brain tumors have very poor outcomes and relatively few treatment options," said Alexander Birbrair, a doctoral student in Delbono's lab and first author of these studies. "Because our cells survived and migrated in the brain, we may be able to use them as drug-delivery vehicles in the future, not only for brain tumors but also for other central nervous system diseases."

In addition, the Wake Forest Baptist team is now conducting research to determine if these neural-like cells also have the capability to become functioning neurons in the central nervous system.

Co-authors of the studies are Tan Zhang, Ph.D., Zhong-Min Wang, M.S., Maria Laura Messi, M.S., Akiva Mintz, M.D., Ph.D., of Wake Forest Baptist, and Grigori N. Enikolopov, Ph.D., of Cold Spring Harbor Laboratory.

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Neural-like stem cells from muscle tissue may hold key to cell therapies for neurodegenerative diseases

Public release date: 12-Oct-2012 [ | E-mail | Share ]

Contact: Marguerite Beck marbeck@wakehealth.edu 336-716-2415 Wake Forest Baptist Medical Center

WINSTON-SALEM, N.C. Oct. 12, 2012 Scientists at Wake Forest Baptist Medical Center have taken the first steps to create neural-like stem cells from muscle tissue in animals. Details of the work are published in two complementary studies published in the September online issues of the journals Experimental Cell Research and Stem Cell Research.

"Reversing brain degeneration and trauma lesions will depend on cell therapy, but we can't harvest neural stem cells from the brain or spinal cord without harming the donor," said Osvaldo Delbono, M.D., Ph.D., professor of internal medicine at Wake Forest Baptist and lead author of the studies.

"Skeletal muscle tissue, which makes up 50 percent of the body, is easily accessible and biopsies of muscle are relatively harmless to the donor, so we think it may be an alternative source of neural-like cells that potentially could be used to treat brain or spinal cord injury, neurodegenerative disorders, brain tumors and other diseases, although more studies are needed."

In an earlier study, the Wake Forest Baptist team isolated neural precursor cells derived from skeletal muscle of adult transgenic mice (PLOS One, Feb.3, 2011).

In the current research, the team isolated neural precursor cells from in vitro adult skeletal muscle of various species including non-human primates and aging mice, and showed that these cells not only survived in the brain, but also migrated to the area of the brain where neural stem cells originate.

Another issue the researchers investigated was whether these neural-like cells would form tumors, a characteristic of many types of stem cells. To test this, the team injected the cells below the skin and in the brains of mice, and after one month, no tumors were found.

"Right now, patients with glioblastomas or other brain tumors have very poor outcomes and relatively few treatment options," said Alexander Birbrair, a doctoral student in Delbono's lab and first author of these studies. "Because our cells survived and migrated in the brain, we may be able to use them as drug-delivery vehicles in the future, not only for brain tumors but also for other central nervous system diseases."

In addition, the Wake Forest Baptist team is now conducting research to determine if these neural-like cells also have the capability to become functioning neurons in the central nervous system.

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Stem cells from muscle tissue may hold key to cell therapies for neurodegenerative diseases

ScienceDaily (Oct. 11, 2012) The generation of functional thyroid tissue from stem cells could allow the treatment of patients, which suffer from thyroid hormone deficiency due to defective function, or abnormal development of the thyroid gland. The team of Sabine Costagliola at the IRIBHM (Universit Libre de Bruxelles) recently developed a protocol that allowed for the first time the efficient generation of functional thyroid tissue from stem cells in mice and published the results of their studies in the scientific journal Nature.

Thyroid hormones are a class of iodide-containing molecules that play a critical role in the regulation of various body function including growth, metabolism and heart function and that are crucial for normal brain development. The thyroid gland, an endocrine organ that has been specialized in trapping iodide, is the only organ where these hormones are produced. It is, however, of note that one out of 3000 human newborns is born with congenital hypothyroidism, a condition characterized by insufficient production of thyroid hormones. In the absence of a medical treatment with thyroid hormones -- initiated during the first days after birth -- the child will be affected by an irreversible mental retardation. Moreover, a life-long hormonal treatment is necessary in order to maintain proper regulation of growth and general metabolism.

By employing a protocol in which two important genes can be transiently induced in undifferentiated stem cells, the researchers at IRIBHM were able to efficiently push the differentiation of stem cells into thyrocytes, the primary cell type responsible for thyroid hormone production in the thyroid gland.

A first exciting finding of these studies was the development of functional thyroid tissue already within the culture dishes. As a next step, the team of Sabine Costagliola transplanted the stem-cell-derived thyrocytes into mice lacking a functional thyroid gland. Four weeks after transplantation, the researchers observed that transplanted mice had re-established normal levels of thyroid hormones in their blood and were rescued from the symptoms associated with thyroid hormone deficiency. These findings have several important implications. First, the cell system employed by the IRIBHM group provides a vital tool to better characterize the molecular processes associated with embryonic thyroid development. Second, the results of the transplantation studies open new avenues for the treatment of thyroid hormone deficiency but also for the replacement of thyroid tissue in patients suffering from thyroid cancer.

The researchers are currently developing a similar protocol based on human stem cells and explore ways to generate functional human thyroid tissue by reprogramming pluripotent stem cells (iPS) derived from skin cells.

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The above story is reprinted from materials provided by Universit Libre de Bruxelles, via AlphaGalileo.

Note: Materials may be edited for content and length. For further information, please contact the source cited above.

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Generation of functional thyroid tissue from stem cells

Friday, Oct. 12, 2012

Stem cells derived from a mouse's skin won Shinya Yamanaka the Nobel Prize in physiology or medicine on Monday. Now researchers in Japan are seeking to use his pioneering technology for an even greater prize: restoring sight.

Scientists at the Riken Center for Developmental Biology in Kobe plan to use induced pluripotent stem (iPS) cells in a human trial using patients with macular degeneration, a disease in which the retina becomes damaged and results in loss of vision, Yamanaka, a Kyoto University professor, told reporters the same day in San Francisco.

Companies including Pfizer Inc. are already planning trials of stem cells derived from human embryos, but Riken's will be the first to use a technology that mimics the power of embryonic cells while avoiding the ethical controversy that accompanies them.

"The work in that area looks very encouraging," John B. Gurdon, 79, a professor at the University of Cambridge who shared this year's Nobel Prize with Yamanaka, said in an interview in London.

Yamanaka and Gurdon split the 8 million Swedish kronor (about 94 million) award for experiments 50 years apart demonstrating that mature cells in latent form retain all of the DNA they had as immature stem cells, and that they can be returned to that potent state.

Their findings offer the potential for a new generation of therapies against hard-to-treat diseases like macular degeneration.

In a study published in 1962, Gurdon took a cell from a tadpole's gut, extracted the nucleus and inserted it into the egg cell of an adult frog whose own nucleus had been removed. The reprogrammed egg cell developed into a tadpole with the genetic characteristics of the original tadpole, and subsequent trials yielded adult frogs.

Yamanaka, 50, built on Gurdon's work by adding four genes to a skin cell from a mouse, returning it to its immature state as a stem cell with the potential to become any cell in the body.

He dubbed them induced pluripotent stem cells.

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Riken to test iPS cells in human trial