A stem cell research project takes an unexpected turn

A stem cell research project takes an unexpected turn

By Arielle Levin Becker Friday, September 2, 2011
Source: ctmirror.org  

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Valerie Horsley and her fellow researchers at Yale University were looking at the role fat cells play in the skin, part of a broader examination into how tissues maintain themselves, when their work took them in a totally unexpected direction: Now they're looking at a potential treatment for baldness.

"I was really surprised that this is the direction we're going in," said Horsley, a professor of molecular, cellular and developmental biology at Yale University. "That's the exciting thing about science. You get to study things you never dreamed you would be doing."

Valerie Horsley

Horsley and the team of researchers found that they could trigger hair growth in mice using stem cells from the fatty layer of skin. They identified the stem cells and found that they produce molecular signals that are necessary for hair growth.

Their research is being published today in the journal Cell, and Horsley says the findings could hold promise for therapies for alopecia and baldness.

"If we can get these fat cells in the skin to talk to the dormant stem cells at the base of hair follicles, we might be able to get hair to grow again," she said.

Don't expect to see fat-laden hair-loss cures on store shelves anytime soon; any potential real-world applications are likely years away. Similar hair growth-inducing signals remain to be identified in humans.

But the findings changed the direction of Horsley's lab. Her main research interest is in how tissues maintain themselves. From her perspective, disease is a problem of the tissue; a person becomes sick when their tissues don't work.

"Bodies have the natural ability to repair themselves in general, so if we can somehow capitalize on that and make that better, then I feel like we can prevent disease," she said.

The hair growth work started with an interest in what fat cells do in the skin. Horsley said she, like most researchers in the field, had paid little attention to the skin's fat cells, aside from a few publications about them in the 1930s.

Horsley's team's work began with the observation that when hair is dead, the layer of fat in the skin is very thin. When hair starts to grow, the fat gets very thick. "We were interested in how that change is happening," she said.

There are two ways the fatty layer could get bigger: Either individual fat cells get larger, or more fat cells get made. Horsley's team found it was the latter--when hair starts to grow, new fat cells are made.

They explored further using mice with defects in different types of fat cells. Mice without mature fat cells in the skin could grow hair relatively normally, but mice with defects in their immature fat cells could not, suggesting that it's the immature fat cells that play a role in activating hair growth. That indicated that it's the turnover and growth of fat cells that's important in driving hair to grow, Horsley said.

The team also transplanted the fat stem cells into mice that had decreased fat cells and abnormal hair growth. After the transplants, their hair grew.

The team theorized that the fat stem cells produce signaling molecules that communicate with cells in the hair. One, called platelet derived growth factor, is highly expressed in immature fat cells.

The Cell article was authored by Eric Festa, Jackie Fretz, Ryan Berry, Barbara Schmidt, Matthew Rodeheffer, Mark Horowitz, and Horsley. The research was funded with money from Yale and the National Institutes of Health.

In the article, the authors noted that patients with obesity, anorexia and lipodystrophy--a disturbance in the way the body produces, uses and stores fat--have defects in their hair follicle growth.

Horsley said the fact that the role fat cells play in skin can be shown means that researchers can now look at whether they are important in other skin processes, like wound healing or tumor formation.

"Now we have the tools to really ask those questions," she said.

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A Hair-Raising Solution?

A Hair-Raising Solution?

In the long-fought battle against baldness, researchers are finally identifying molecular pathways that an be manipulated to generate new hair follicles.

By Dan Cossins | September 1, 2013
Source: the-scientist.com




For some men, few things are more worrisome than the daily sight of an ever-receding hairline in the bathroom mirror, or the peach-fuzz feel of a thinning crown. This creeping nemesis—known as male-pattern baldness or androgenetic alopecia—emerges in genetically predisposed individuals when a by-product of testosterone called dihydrotestosterone (DHT) causes hair follicles on the scalp to shrink, producing ever thinner hairs, until the follicles eventually lose the capacity to produce hair that protrudes above the surface of the skin.

For the moment, there are few treatment options. The only two approved by the US Food and Drug Administration are minoxidil (Rogaine), a vasodilator thought to prevent or slow follicle miniaturization by increasing nutrient supply, and finasteride (Propecia), which achieves the same goals by blocking the conversion of testosterone into DHT. Research has shown that both can prevent or slow hair loss, and sometimes induce regrowth, by rescuing follicles that have recently begun to miniaturize. But neither can revive totally shrunken follicles. And while relocating healthy follicles to barren patches can solve the problem, hair transplant procedures are expensive and invasive.

The ultimate victory, when it comes to the long-fought battle against baldness, would be to find a way to trick the body into creating brand-new hair follicles.

Researchers first raised the possibility in the 1950s, when they observed new hair follicles forming during wound healing in rabbits and mice, but the work was later discredited. Then, in 2007, George Cotsarelis, a dermatologist at the University of Pennsylvania’s Perelman School of Medicine, spotted hairs growing in the middle of small cuts they’d made in the skin of adult mice. “We figured out they were de novo hair follicles formed in a process that looked a lot like embryogenesis,” says Cotsarelis.

It turns out that the wound-healing process causes skin cells to dedifferentiate, providing a limited time window during which those cells can be persuaded to form new hair follicles. Even more intriguingly, the researchers also found that inhibiting Wnt signaling during this window reduced follicle neogenesis, while overexpressing Wnt molecules in the skin increased the number of new follicles (Nature, 447:316-20, 2007). Cotsarelis and his colleagues had discovered a potential way to generate new hair follicles.

PureTech Ventures, a Boston-based venture capital group, snapped up the research even before the paper had come out. PureTech’s Daphne Zohar, David Steinberg, and Bernat Olle had previously recruited Cotsarelis to help explore commercial opportunities arising from dermatological research. Having evaluated hundreds of existing patents without finding anything to form a company around, Cotsarelis began to reveal the molecular machinery behind follicular regeneration in mice—a finding with obvious commercial potential. “I thought, gee, this is perfect for PureTech,” he recalls. In 2006, Cotsarelis, Zohar, Steinberg, Olle, and several other scientists cofounded a company called Follica to develop new combination therapies to induce follicle neogenesis.

Although Follica has released few details on their proprietary procedure, the general idea is clear: their patented minimally invasive “skin perturbation” device removes the top layers of skin, causing the underlying skin cells to revert to a stem-like state, after which a molecule is applied topically to direct the formation of new hair follicles.

Indeed, Follica has already done preclinical and clinical trials, says Olle, “all of which confirm that we can consistently create new hair follicles in mice and in humans. As far as I know, no other approach has been able to achieve that.”

News of the progress has attracted strong interest from the public, with comments piling up below online articles about Follica and serving as de facto message boards for the science-savvy bald community to exchange expressions of hope and skepticism—and to speculate about when the “cure” might hit the market. Earlier this year, Cotsarelis’s group sparked another comment frenzy by demonstrating that a protein called fibroblast growth factor 9 (Fgf9), which is secreted by gamma delta (γδ) T cells in the dermis, plays a key role in the formation of new follicles during wound healing in adult mice.

Very little is known about the mechanism of hair follicle neogenesis besides the Wnt family, so the discovery of Fgf9 was very important.

When Cotsarelis and his collaborators inhibited Fgf9, fewer new follicles formed compared to controls. And when the researchers induced overexpression of Fgf9, new follicle formation increased 2–3-fold compared with normal expression. That’s because Fgf9 initiates a feedback loop in wound fibroblasts that amplifies the signaling factors required for follicle neogenesis, explains Cotsarelis. Importantly, even when the researchers added Fgf9 to wounds in knockout mice engineered to lack γδ T cells (which are rare in humans), they observed increased Fgf9 expression in fibroblasts—and hair regeneration (Nature Medicine, 19:916-23, 2013).

“Very little is known about the mechanism of hair follicle neogenesis besides the Wnt family, so the discovery of Fgf9 was very important,” says Luis Garza, a dermatologist at Johns Hopkins School of Medicine who has previously collaborated with Cotsarelis but was not involved in this research. “There are probably a whole panoply of agents which control regeneration,” but this study demonstrates Fgf9’s potential as a baldness therapy.

The next step is to test the effects of Fgf9 on human skin in xenograft models and then in the clinic. “If results hold up in humans, we could expect a several-fold increase in new follicles beyond what we were already accomplishing,” says Olle.

There is a long way to go, of course, and Garza points out that “there are myriad questions regarding moving Fgf9 to human use.” But the recent advances by Cotsarelis and Follica are raising fresh shoots of hope for people who are losing or have already lost their hair. For Cotsarelis, that means more e-mails from interested members of the public, something he’s gotten used to over the last 5 years.

“I’ve learned to accept that I’m the baldness guy,” he says. “Everybody asks about it, but I don’t get sick of it. It’s nice to work in an area that people care about.”

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Cloning: The future in hair transplants

Cloning: The future in hair transplants

Date: Visited September 7th, 2013
Source: ilterclinic.com

At the Ilter Clinic, we pay constant attention to new scientific and technical advancements in hair transplantation. We are also active in researching new progress in the field so that ever-better techniques may be developed in the future.



High-tech research is providing new hope. These methods are still far from becoming commercially available, but gene therapy and cloning may one day reduce limitations we face in the donor area.

Gene therapy

The idea behind gene therapy is to introduce new DNA into a patient’s hair cells. The new DNA would prevent cells from being affected by the DHT (dihydrotestosteron) hormone that causes Male Pattern Baldness.



However, the research is still in its infancy. Some genes have already been identified as the cause behind hair loss, but there are still many other factors to be considered. With this in mind, a great deal of research needs to be done before gene therapy becomes a reality.

Hair cloning

Cloning hair follicles is a new technology. Even though it is considered something of a Holy Grail for people suffering from hair loss because of the potential for an unlimited supply of hair from a single strand, cloning hair follicles is keenly debated. There have been exciting breakthroughs, but the method needs another ten years of research before it is commercially available.

There are two organizations seriously researching a commercially viable way to multiply hair loss-resistant donor follicles. They are Aderans, headquartered in Japan, and Intercytex, based in England.

Hair cloning is a lay term for tissue-developed hair growth. The approach being pursued involves extracting single hair cells from the hair loss-resistant donor area and attempting to replicate them in the laboratory. These "dermal papilla" cells mature into hair follicles in a process known as follicular neogenesis. If they can be stimulated to multiply, then theoretically there is no limit to the number of hair follicles that could be grown in the laboratory and transplanted onto a person’s scalp.



However, controlling the direction of new hair growth from cloned follicles has been problematic. Many people believe hair cell implants will initially be used as filler hair, primarily on the top and crown areas, while critical areas such as the hairline will continue to receive transplants using conventional FUE grafts. Also, the cost of this laboratory-intensive procedure is expected to exceed conventional hair transplantation when it is introduced.

At this point in time, it is not recommended that patients wait for cloning. If and when hair cell implants arrive in the future, they could well be used to create even greater levels of density and fullness behind the transplanted hairline.

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