Cells’ Knack for Hoarding Proteins Inadvertently Kickstarts the Aging Process

Even cells need to take out the trash—mostly damaged or abnormal proteins—in order to maintain a healthy clean environment. And scientists are now uncovering the harmful effects when cells instead begin to hoard their garbage.

Cells' penchant for hoarding proteins may spur the cellular aging process, according to new research.

Cells’ penchant for hoarding proteins may spur the cellular aging process, according to new research. [Labyrinth (1986)]

Aging, on the cellular level is—at its core—the increasing inability for cells to repair themselves over time. As cells begin to break down faster than they can be repaired, the risk of age-related diseases escalates. Cancer, heart disease and neurological conditions such as Alzheimer’s disease are some of aging’s most deadly effects.

As a result, scientists have long searched for ways to give our cells a little help and improve our quality of life as we age. For example, recent research has pointed to a connection between fasting (restricting calories) and a longer lifespan, though the molecular mechanisms behind this connection remain somewhat cryptic.

But now Dr. Daniel Gottschling, a scientist at the Fred Hutchinson Cancer Research Center and an aging expert, has made extraordinary progress toward solving some of the mysteries of aging.

In two studies published this month in the Proceedings of the National Academy of Sciences and eLife, Gottschling and colleagues discover that a particular long-lasting protein builds up over time in certain cell types, causing the buildup of a protein hoard that damages the cell beyond repair.

Clearing out the Cobwebs

Some cells, such as those that make up the skin or that reside in the gut, are continually replenished by a stockpile of adult stem cells. But other cells, such as those found in the eye and brain, last for years, decades and—in some cases—our entire lifetimes.

Within and surrounding these long-lived cells are similarly long-lived proteins which help the cell perform essential functions. For example, the lens of the human eye, which helps focus light, is made up of these proteins that arise during embryonic development and last for a lifetime.

Dr. Daniel Gottschling is looking to unlock the mysteries behind cellular aging.

Dr. Daniel Gottschling is looking to unlock the mysteries behind cellular aging. [Image courtesy of the Fred Hutchinson Cancer Research Center]

“Shortly after you’re born, that’s it, you get no more of that protein and it lives with you the rest of your life,” explained Gottschling.

As a result, if those proteins degrade and die, new ones don’t replace them—the result is the age-related disease called cataracts.

But scientists weren’t exactly sure of the relationship between these dying proteins and the onset of conditions such as cataracts, and other disease related to aging. Did these conditions occur because the proteins were dying? Or rather because the proteins were building up to toxic levels?

So Gottschling and his team set up a series of experiments to find out.

Stashing Trash

They developed a laboratory model by using yeast cells. Interestingly, yeast cells share several key properties with human stem cells, and are often the focus of early-stage research into basic, fundamental concepts of biology.

Like stem cells, yeast cells grow and divide asymmetrically. In other words, a ‘mother’ cell will produce many ‘daughter’ cells, but will itself remain intact. In general, yeast mother cells produce up to 35 daughter cells before dying—which usually takes just a few days.

 Yeast “mother” cells budding and giving birth to newborn “daughter” cells.  [Image courtesy of Dr. Kiersten Henderson / Gottschling Lab]

Yeast “mother” cells budding and giving birth to newborn “daughter” cells.
[Image courtesy of Dr. Kiersten Henderson / Gottschling Lab]

Here, the research team used a special labeling technique that marked individual proteins that exist within and surrounding these mother cells. These microscopic tracking devices then told researchers how these proteins behaved over the entire lifespan of the mother cell as it aged.

The team found a total of 135 long-lived proteins within the mother cell. But what really surprised them was what they found upon closer examination: all but 21 of these 135 proteins appeared to have no function. They appeared to be trash.

“No one’s ever seen proteins like this before [in aging],” said Nathanial Thayer, a graduate student in the Gottschling Lab and lead author of one of the studies.

Added Gottschling, “With the number of different fragments [in the mother cell], we think they’re going to cause trouble. As the daughter yeast cells grow and split off, somehow mom retains all these protein bits.”

This startling discovery opened up an entirely new set of questions, explained Gottschling.

“It’s not clear whether the mother’s trash keeper function is a selfless act designed to give her daughters the best start possible, or if she’s hanging on to them for another reason.”

Hungry, Hoarding Mother Cells

So Gottschling and his team took a closer look at one of these proteins, known as Pma1.

Recent work by the Gottschling Lab found that cells lose their acidity over time, which itself leads to the deterioration of the cells’ primary energy source. The team hypothesized that Pma1 was somehow intricately tied to corresponding levels of pH (high pH levels indicate an acidic environment, while lower pH levels signify a more basic environment).

In the second study published in eLife, led by Postdoctoral Fellow Dr. Kiersten Henderson, the team made several intriguing discoveries about the role of Pma1.

First, they uncovered a key difference between mother and daughter cells: daughter cells are born with no Pma1. As a result, they are far more acidic than their mothers. But when they ramped up Pma1 in the mother cells, the acidity levels in subsequent generations of daughter cells changed accordingly.

“When we boosted levels of the protein, daughter cells were born with Pma1 and became more basic (they had a lower pH), just like their mothers.”

Further examination uncovered the true relationship between Pma1 and these cells. At its most fundamental, Pma1 helps the mother cells eat.

“Pma1 plays a key role in cellular feeding,” said Gottschling. “The protein sits on the surface of cells and helps them take in nutrients from their environment.”

Pma1 gives the mother cell the ability to gorge herself. The more access to food she has, the easier it is for her to produce more daughter cells. By hoarding Pma1, the mother cell can churn out more offspring. Unfortunately, she is also signing her own death certificate—she’s creating a more basic environment that, in the end, proves toxic and contributes to her death.

The hoarding, it turns out, may not all be due to the mother cells’ failure to ‘take out the trash.’ Instead, she wants to keep eating and producing daughters—and hoarding Pma1 allows her to do just that.

“There’s this whole trade off of being able to divide quickly and the negative side is that the individual, the mother, does not get to live as long.”

Together, the results from these two studies provide a huge boost for researchers like Gottschling who are trying to unravel the molecular mysteries of aging. But the process is incredibly intricate, and there will likely be no one simple solution to improving quality of life as we get older.

“The whole issue of aging is so complex that we’re still laying the groundwork of possibilities of how things can go awry,” said Gottschling. “And so we’re still learning what is going on. We’re defining the aging process.”

New Cellular Tracking Device Tests Ability of Cell-Based Therapies to Reach Intended Destination

Therapies aimed at replacing damaged cells with a fresh, healthy batch hold immense promise—but there remains one major sticking point: once you have injected new, healthy cells into the patient, how do you track them and how do you ensure they do the job for which they were designed?

New tracking technique could improve researchers' ability to test potential cell therapies.

New tracking technique could improve researchers’ ability to test potential cell therapies.

Unfortunately, there’s no easy solution. The problem of tracking the movement of cells during cell therapy is that it’s hard to stay on their trail they enter the body. They can get mixed up with other, native cells, and in order to test whether the therapy is working, doctors often have to rely on taking tissue samples.

But now, scientists at the University of California, San Diego School of Medicine and the University of Pittsburgh have devised an ingenious way to keep tabs on where cells go post injection. Their findings, reported last week in the journal Magnetic Resonance in Medicine, stand to help researchers identify whether cells are arriving at the correct destination.

The research team, lead by UCSD Radiology Professor Dr. Eric Ahrens, developed something called a periflourocarbon (PFC) tracer in conjunction with MRI technology. Testing this new technology in patients receiving immune cell therapy for colorectal cancer, the team found that they were better able to track the movement of the cells than with traditional methods.

“This is the first human PFC cell tracking agent, which is a new way to do MRI cell tracking,” said Ahrens in a news release. “It’s the first example of a clinical MRI agent designed specifically for cell tracking.”

They tagged these cells with atoms of fluorine, a compound that normally occurs at extremely low levels. After tagging the immune cells, the researchers could then see where they went after being injected. Importantly, the team found that more than one-half of the implanted cells left the injection site and headed towards the colon. This finding marks the first time this process had been so readily visible.

Ahrens explained the technology’s potential implications:

“The imaging agent technology has been shown to be able to tag any cell type that is of interest. It is a platform imaging technology for a wide range of diseases and applications.”

A non-invasive cell tracking solution could serve as not only as an attractive alternative to the current method of tissue sampling, it could even help fast-track through regulatory hurdles new stem cell-based therapies. According to Ahrens:

“For example, new stem cell therapies can be slow to obtain regulatory approvals in part because it is difficult, if not impossible, with current approaches to verify survival and location of transplanted cells…. Tools that allow the investigator to gain a ‘richer’ data set from individual patients mean it may be possible to reduce patient numbers enrolled in a trial, thus reducing total trial cost.”

What are the ways scientists see stem cells in the body? Check out our Spotlight Video on Magnetic Particle Imaging.

Harder, Better, Faster, Stronger: Scientists Work to Create Improved Immune System One Cell at a Time

The human immune system is the body’s best defense against invaders. But even our hardy immune systems can sometimes be outpaced by particularly dangerous bacteria, viruses or other pathogens, or even by cancer.

Salk Institute scientists have developed a new cellular reprogramming technique that could one day boost a weakened immune system.

Salk Institute scientists have developed a new cellular reprogramming technique that could one day boost a weakened immune system.

But what if we could give our immune system a boost when it needs it most? Last week scientists at the Salk Institute for Biological Sciences devised a new method of doing just that.

Reporting in the latest issue of the journal Stem Cells, Dr. Juan Carlos Izpisua Belmonte and his team announce a new method of creating—and then transplanting—white blood cells into laboratory mice. This new and improved method could have significant ramifications for how doctors attack the most relentless disease.

The authors achieved this transformation through the reprogramming of skin cells into white blood cells. This process builds on induced pluripotent stem cell, or iPS cell, technology, in which the introduction of a set of genes can effectively turn one cell type into another.

This Nobel prize-winning approach, while revolutionary, is still a many months’ long process. In this study, the Salk team found a way to shorten the cellular ‘reprogramming’ process from several months to just a few weeks.

“The process is quick and safe in mice,” said Izpisua Belmonte in a news release. “It circumvents long-standing obstacles that have plagued the reprogramming of human cells for therapeutic and regenerative purposes.”

Traditional reprogramming methods change one cell type, such as a skin cell, into a different cell type by first taking them back into a stem cell-like, or ‘pluripotent’ state. But here, the research team didn’t take the cells all the way back to pluripotency. Instead, they simply wiped the cell’s memory—and gave it a new one. As first author Dr. Ignacio Sancho-Martinez explained:

“We tell skin cells to forget what they are and become what we tell them to be—in this case, white blood cells. Only two biological molecules are needed to induce such cellular memory loss and to direct a new cell fate.”

This technique, which they dubbed ‘indirect lineage conversion,’ uses the molecule SOX2 to wipe the skin cell’s memory. They then use another molecule called miRNA 125b to reprogram the cell into a white blood cell.

These newly generated cells appear to engraft far better than cells derived from traditional iPS cell technology, opening the door to therapies that more effectively introduce these immune cells into the human body. As Sanchi-Martinez so eloquently stated:

“It is fair to say that the promise of stem cell transplantation is now closer to realization.”

CIRM-Funded Scientists Test Recipe for Building New Muscles

When muscles get damaged due to disease or injury, the body activates its reserves—muscle stem cells that head to the injury site and mature into fully functioning muscle cells. But when the reserves are all used up, things get tricky.

Scientists at Sanford-Burnham may have uncovered the key to muscle repair.

Scientists at Sanford-Burnham may have uncovered the key to muscle repair.

This is especially the case for people living with muscle diseases, such as muscular dystrophy, in which the muscle degrades at a far faster rate than average and the body’s reserve stem cell supply becomes exhausted. With no more supply from which to draw new muscle cells, the muscles degrade further, resulting in the disease’s debilitating symptoms, such as progressive difficulty walking, running or speaking.

So, scientists have long tried to find a way to replenish the dwindling supply of muscle stem cells (called ‘satellite cells’), thus slowing—or even halting—muscle decay.

And now, researchers at the Sanford-Burnham Medical Research Institute have found a way to tweak the normal cycle, and boost the production of muscle cells even when supplies appear to be diminished. These findings, reported in the latest issue of Nature Medicine, offer an alternative treatment for the millions of people suffering not only from muscular dystrophy, but also other diseases that result in muscle decay—such as some forms of cancer and age-related diseases.

In this study, Sanford-Burnham researchers found that introducing a particular protein, called a STAT3 inhibitor, into the cycle of muscle-cell regeneration could boost the production of muscle cells—even after multiple rounds of repair that would otherwise render regeneration virtually impossible.

The STAT3 inhibitor, as its name suggests, works by ‘inhibiting,’ or effectively neutralizing, another protein called STAT3. Normally, STAT3 gets switched on in response to muscle injury, setting in motion a series of steps that replenishes muscle cells.

In experiments first in animal models of muscular dystrophy—and next in human cells in a petri dish—the team decided to modify how STAT3 functions. Instead of keeping STAT3 active, as would normally occur, the team introduced the STAT3 inhibitor at specific times during the muscle regeneration process. And in so doing, noticed a significant boost in muscle cell production. As Dr. Alessandra Sacco, the study’s senior author, stated in a news release:

“We’ve discovered that by timing the inhibition of STAT3—like an ‘on/off’ light switch—we can transiently expand the satellite cell population followed by their differentiation into mature cells.”

This approach to spurring muscle regeneration, which was funded in part by a CIRM training grant, is not only innovative, but offers new hope to a disease for which treatments have offered little. As Dr. Vittorio Sartorelli, deputy scientific director of the National Institute of Arthritis and Musculoskeletal and Skin Diseases (NIAMS), stated:

“Currently, there is no cure to stop or reverse any form of muscle-wasting disorders—only medication and therapy that can slow the process. A treatment approach consisting of cyclic bursts of STAT3 inhibitors could potentially restore muscle mass and function in patients, and this would be a very significant breakthrough.”

Sacco and her colleagues are encouraged by these results, and plan to explore their findings in greater detail—hopefully moving towards clinical trials:

“Our next step is to see how long we can extend the cycling pattern, and test some of the STAT3 inhibitors currently in clinical trials for other indications such as cancer, as this could accelerate testing in humans.”

Stem Cell Stories that Caught our Eye: What’s the Best Way to Treat Deadly Cancer, Destroying Red Blood Cells’ Barricade, Profile of CIRM Scientist Denis Evseenko

Here are some stem cell stories that caught our eye this past week. Some are groundbreaking science, others are of personal interest to us, and still others are just fun.

Stem Cells vs. Drugs for Treating Deadly Cancer. When dealing with a potentially deadly form of cancer, choosing the right treatment is critical. But what if that treatment also poses risks, especially for older patients? Could advances in drug development render risky treatments, such as transplants, obsolete?

That was the focus of a pair of studies published this week in the New England Journal of Medicine, where a joint Israeli-Italian research team investigated the comparative benefits of two different treatments for a form of cancer called multiple myeloma.

Multiple myeloma attacks the body’s white blood cells. While rare, it is one of the most deadly forms of cancer—more than half of those diagnosed with the disease do not survive five years after being diagnosed. The standard form of treatment is usually a stem cell transplant, but with newer and better drugs coming on the market, could they render transplants unnecessary?

In the twin studies, the research team divided multiple myeloma patients into two groups. One received a combination of stem cell transplant and chemotherapy, while the other received a combination of drugs including melphalan, prednisone and lenalidmomide. After tracking these patients over a period of four years, the research team saw a clear advantage for those patients that had received the transplant-chemotherapy treatment combination.

To read more about these twin studies check out recent coverage in NewsMaxHealth.

Breaking Blood Cells’ Barricade. The process whereby stem cells mature into red blood cells is, unfortunately, not as fast as scientists would like. In fact, there is a naturally occurring barrier that keeps the production relatively slow. In a healthy person this is not necessarily a problem, but for someone in desperate need of red blood cells—it can prove to be very dangerous.

Luckily, scientists at the University of Wisconsin-Madison have found a way to break through this barrier by switching off two key proteins. Once firmly in the ‘off’ position, the team could boost the production of red blood cells.

These findings, published in the journal Blood, are critical in the context of disease anemia, where the patient’s red blood cell count is low. They also may lead to easier methods of stocking blood banks.

Read more about this exciting discovery at HealthCanal.

CIRM Scientist on the Front Lines of Cancer. Finally, HealthCanal has an enlightening profile of Dr. Denis Evseenko, a stem cell scientist and CIRM grantee from the University of California, Los Angeles (UCLA).

Born in Russia, the profile highlights Evseenko’s passion for studying embryonic stem cells—and their potential for curing currently incurable diseases. As he explains in the article:

“I had a noble vision to develop progressive therapies for the patient. It was a very practical vision too, because I realized how limited therapeutic opportunities could be for the basic scientist, and I had seen many great potential discoveries die out before they ever reached the clinic. Could I help to create the bridge between stem cells, research and actual therapeutics?”

Upon arriving at UCLA, Evseenko knew he wanted to focus this passion into the study of degenerative diseases and diseases related to aging, such as cancer. His bold vision of bridging the gap between basic and translational research has earned him support not only from CIRM, but also the National Institutes of Health and the US Department of Defense, among others. Says Evseenko:

“It’s my hope that we can translate the research we do and discoveries we make here to the clinic to directly impact patient care.”

Throwback Thursday: Scientists Create Synthetic Version of Earth’s Earliest Primordial Cells

Cells as we know them today—no matter the species—are feats of evolution; molecular machines with thousands of interlocking parts. But they didn’t start out that way.

Scientists have built a simplified cell membrane that mimics natural cellular processes and movements.

Scientists have built a simplified cell membrane that mimics natural cellular processes and movements.

Using the latest tools from the new field of synthetic biology, a team of biophysicists from Tecnische Universitaet Muenchen (TUM) in Munich, Germany, has constructed a synthetic version of an early cell, complete with some biomechanical function.

To build a primordial cell, the recipe is simple: all you need is a membrane shell, a couple of biomolecules that perform the most basic of functions, and some fuel to keep it going.

Here, TUM researchers used lipids (fat molecules) to create a double-layer cellular membrane that mimics a cell’s natural membrane. They then filled the membrane with microtubules, which acted as cellular ‘scaffolding’ to hold everything in place, and another molecule called ‘kinesin.’ These kinesin molecules serve as molecular ‘motors,’ transporting components throughout the cell by traveling along the microtubule scaffolding. Finally, they added the fuel: a compound called adenosine triphosphate, or ATP. The scientists likened this set-up to a liquid crystal layer within the membrane that is in a permanent state of motion. As lead author Felix Keber explained in a news release:

“One can picture the liquid crystal layer as tree logs drifting on the surface of a lake. When it becomes too congested, they line up in parallel but can still drift alongside each other.”

Once constructed, the research team then wanted to understand how these synthetic cells behaved, and if it would mimic natural cellular movements. And much to the team’s surprise—they did.

During a process called osmosis—where water droplets selectively pass through the membrane—the researchers noticed a change in the cells’ shape as water left the interior of the cell. The resulting membrane slack was causing the microtubules to stick out like spikes. These ‘spiked extensions’ were eerily similar to what the extensions that scientists have seen cells normally use to get around.

This observation cleared up a long-standing mystery: the way cells change shape and move around wasn’t random. The cells were simply following the basic laws of physics. This discovery then led the team to uncover the underlying mechanisms of other cellular behaviors—and even make predictions on other systems.

As the study’s lead author, Professor Andreas Bausch, stated in the same release:

“With our synthetic biomolecular model we have created a novel option for developing minimal cell models. It is ideally suited to increasing the complexity in a modular fashion in order to reconstruct cellular processes like cell migration or cell division in a controlled manner.”

In the future, the team hopes to build this knowledge to a point where they can understand the physical basis for deformed cells—with potential applications to disease modeling. Bausch added:

“That the artificially created system can be comprehensively described from a physical perspective gives us hope that in the next steps we will also be able to uncover the basic principles behind the manifold cell deformations.”

Body’s own Healing Powers Could be Harnessed to Regrow Muscle, Wake Forest Study Finds

Imagine being able to repair muscle that had been damaged in an injury, not by transplanting new muscle or even by transplanting cells, but rather simply by laying the necessary groundwork—and letting the body do the rest.

The ability for the human body to regenerate tissues lost to injury or disease may still be closer to science fiction than reality, but scientists at the Wake Forest Baptist Medical Center in Winston-Salem, North Carolina, have gotten us one big step closer.

Reporting in the latest issue of the journal Acta Biomaterialia, Dr. Sang Jin Lee and his research team describe their ingenious new method for regrowing damaged muscle tissue in laboratory rodents—by supercharging the body’s own natural restorative abilities. As Lee explained in a news release:

“Working to leverage the body’s own regenerative properties, we designed a muscle-specific scaffolding system that can actively participate in functional tissue regeneration. This is a proof-of-concept study that we hope can one day be applied to human patients.”

Normally, the body’s muscles—as well as the majority of organs—sit atop a biological ‘scaffold’ created by a matrix of molecules secreted by surrounding cells. This scaffold gives the organs and muscle their three-dimensional structure.

Scientists have identified a protein that may help spur 'in body' muscle regeneration.

Scientists have identified a protein that may help spur ‘in body’ muscle regeneration.

As of right now, if doctors want to replace damaged muscle they have one of two options: either surgically transfer a muscle segment from one part of the body to the other, or engineer replacement muscle tissue in the lab from a biopsy. Both methods, while doable, are not ideal. In the first, you are reducing the strength of the donor muscle; in the second, you have the added challenge of standardizing the engineered cells so that they will graft successfully.

So, Lee and his team focused on a third way: coaxing the body’s own supply of adult stem cells—which are tissue specific and normally used for general small-scale maintenance—to rebuild the damaged muscle from within. Said Lee:

“Our aim was to bypass the challenges of both of these techniques and to demonstrate the mobilization of muscle cells to a target-specific site for muscle regeneration.”

In this study, the researchers developed a method to do just that in the laboratory animals. First, they implanted a new cellular scaffold into the rodents’ legs. After several weeks, they removed the scaffold to see whether any cells had latched on of their own accord.

Interestingly, the team found that without any additional manipulation, the scaffold had developed a network of blood vessels within just four weeks after implanting. They also observed the presence of some early-stage muscle cells. What the researchers wanted to do next was find a way to boost what they already observed naturally.

To do so, they tested whether proteins—previously known to be involved in muscle development—could boost the speed and amount of recruitment of muscle stem cells to the scaffold.

After a series of experiments, they found a leading candidate: a protein called insulin-like growth factor 1, or IGF-1. And when they injected IGF-1 into the newly-implanted scaffolds the difference was remarkable. These scaffolds had about four times as many cells when compared to the plain scaffolds. As Lee explained:

“The protein effectively promoted cell recruitment and accelerated muscle regeneration.”

The real work now begins, added Lee, whose team will now take their research to larger animal models, such as pigs, to see whether their technique can work on a far grander scale.

Stem Cell Stories that Caught our Eye: A Zebrafish’s Stripes, Stem Cell Sound Waves and the Dangers of Stem Cell Tourism

Here are some stem cell stories that caught our eye this past week. Some are groundbreaking science, others are of personal interest to us, and still others are just fun.

The zebrafish (Danio rerio) owes its name to a repeating pattern of blue stripes alternating with golden stripes. [Credit: MPI f. Developmental Biology/ P. Malhawar]

The zebrafish (Danio rerio) owes its name to a repeating pattern of blue stripes alternating with golden stripes. [Credit: MPI f. Developmental Biology/ P. Malhawar]

How the Zebrafish Got its Stripes. Scientists in Germany have identified the different pigment cells that emerge during embryonic development and that determine the signature-striped pattern on the skins of zebrafish—one of science’s most commonly studied model organisms. These results, published this week in the journal Science, will help researchers understand how patterns, from stripes to spots to everything in between, develop.

In the study, scientists at the Max Planck Institute for Developmental Biology mapped how three distinct pigment cells, called black cells, reflective silvery cells, and yellow cells emerge during development and arrange themselves into the characteristic stripes. While researchers knew these three cell types were involved in stripe formation, what they discovered here was that these cells form when the zebrafish is a mere embryo.

“We were surprised to observe such cell behaviors, as these were totally unexpected from what we knew about color pattern formation”, says Prateek Mahalwar, first author of the study, in a news release.

What most surprised the research team, according to the news release, was that the three cell types each travel across the embryo to form the skin from a different direction. According to Dr. Christiane Nüsslein-Volhard, the study’s senior author:

“These findings inform our way of thinking about color pattern formation in other fish, but also in animals which are not accessible to direct observation during development such as peacocks, tigers and zebras.”

Sound Waves Dispense Individual Stem Cells. It happens all the time in the lab: scientists need to isolate and study a single stem cell. The trick is, how best to do it. Many methods have been developed to achieve this goal, but now scientists at the Regenerative Medicine Institute (REMEDI) at NUI Galway and Irish start-up Poly-Pico Technologies Ltd. have pioneered the idea of using sound waves to isolate living stem cells, in this case from bone marrow, with what they call the Poly-Pico micro-drop dispensing device.

Poly-Pico Technologies Ltd., a start-up that was spun out from the University of Limerick in Ireland, has developed a device that uses sound energy to accurately dispense protein, antibodies and DNA at very low volumes. In this study, REMEDI scientists harnessed this same technology to dispense stem cells.

These results, while preliminary, could help improve our understanding of stem cell biology, as well as a number of additional applications. As Poly-Pico CEO Alan Crean commented in a news release:

“We are delighted to see this new technology opportunity emerge at the interface between biology and engineering. There are other exciting applications of Poly-Pico’s unique technology in, for example, drug screening and DNA amplification. Our objective here is to make our technology available to companies, and researchers, and add value to what they are doing. This is one example of such a success.”

The Dangers of Stem Cell Toursim. Finally, a story from ABC News Australia, in which they recount a woman’s terrifying encounter with an unproven stem cell technique.

In this story, Annie Levington, who has suffered from multiple scleoris (MS) since 2007, tells of her journey from Melbourne to Germany. She describes a frightening experience in which she paid $15,000 to have a stem cell transplant. But when she returned home to Australia, she saw no improvement in her MS—a neuroinflammatory disease that causes nerve cells to whither.

“They said I would feel the effects within the next three weeks to a year. And nothing – I had noticed nothing whatsoever. [My neurologist] sent me to a hematologist who checked my bloods and concluded there was no evidence whatsoever that I received a stem cell transplant.”

Sadly, Levington’s story is not unusual, though it is not as dreadful as other instances, in which patients have traveled thousands of miles to have treatments that not only don’t cure they condition—they actually cause deadly harm.

The reason that these unproven techniques are even being administered is based on a medical loophole that allows doctors to treat patients, both in Australia and overseas, with their own stem cells—even if that treatment is unsafe or unproven.

And while there have been some extreme cases of death or severe injury because of these treatments, experts warn that the most likely outcome of these untested treatments is similar to Levington’s—your health won’t improve, but your bank account will have dwindled.

Want to learn more about the dangers of stem cell tourism? Check out our Stem Cell Tourism Fact Sheet.

A Tumor’s Trojan Horse: CIRM Researchers Build Nanoparticles to Infiltrate Hard-to-Reach Tumors

Some tumors are hard to find, while others are hard to destroy. Fortunately, a new research study from the University of California, Davis, has developed a new type of nanoparticle that could one day do both.

UC Davis scientists have developed a new type of nanoparticle to target tumor cells.

UC Davis scientists have developed a new type of nanoparticle to target tumor cells.

Reporting in the latest issue of Nature Communications, researchers in the laboratory of UC Davis’ Dr. Kit Lam describe a type of ‘dynamic nanoparticle’ that they created, which not only lights up tumors during an MRI or PET scan, but which may also serve as a microscopic transport vehicle, carrying chemotherapy drugs through the blood stream—and releasing them upon reaching the tumor.

This is not the first time scientists have attempted to develop nanoparticles for medicinal purposes, but is perhaps one of the more successful. As Yuanpei Li, one of the study’s co-first authors stated in a news release:

“These are amazingly useful particles. As a contrast agent, they make tumors easier to see on MRI and other scans. We can also use them as vehicles to deliver chemotherapy directly to tumors.”

Nanoparticles can be constructed out of virtually any material—but the material used often determines for what purpose they can be used. Nanoparticles made of gold-based materials, for example, may be strong for diagnostic purposes, but have been shown to have issues with safety and toxicity. On the flip side, nanoparticles made from biological materials are safer, but inherently lack imaging ability. What would be great, the team reasoned, was a new type of nanoparticle that had the best qualities of both.

In this study, which was funded in part by CIRM, Lam and the UC Davis team devised a new type of nanoparticle that was ‘just right,’—simple to make, safe and able to perform the desired task, in this case: attack tumors.

Built of organic porphyrin and cholic acid polymers and coated with the amino acid cysteine, the 32 nanometer-wide particles developed in this study offer a number of advantages over other models. They are small enough to pass into tumors, can be filled with a chemo agent and with a specially designed cysteine coating, and don’t accidentally release their payload before reaching their destination.

And this is where the truly ingenious part kicks in. With a simple flash of light, the researchers could direct the particles to drop their payload—at just the right time, offering some intriguing possibilities for new ways to deliver chemotherapy drugs.

But wait, there’s more. The fact that these new particles, which the team are calling cysteine nanoparticles, or CNP’s, appear to congregate inside tumors means that they also end up being easy to spot on an MRI.

Continued Li in the same release:

“These particles can combine imaging and therapeutics. We could potentially use them to simultaneously deliver treatment and monitor treatment efficacy. This is the first nanoparticle to perform so many different jobs. From delivering chemo, photodynamic and photothermal therapies to enhancing diagnostic imaging. It’s the complete package.”

And while the team cautions that these results are preliminary, they open the door to an entirely new and far more exact method of drug delivery to tumors—no matter how well-hidden in the body they may be.

First of its kind stem cell production facility sets its sights on deadly childhood disease

We are used to hearing about immune suppression when transplanting organs or cells from one person to another. It’s a necessary step in preventing the body from attacking the transplanted material. Now Children’s Hospital of Orange County (CHOC) has just unveiled its newest tool to treat rare childhood diseases. Instead of focusing on immune suppression this focuses on immune-matching.

CHOC's new stem cell production facility

CHOC’s new stem cell production facility

CHOC has opened up a new stem cell production facility. It’s funded by CIRM and it’s a state-of-the-art mini clean room/manufacturing facility that will allow researchers to produce patient-specific cells for future immune-matching therapies.

“We are excited. We’ve been planning this for at least five years,” says Philip Schwartz, Ph.D., senior scientist at the CHOC Children’s Research Institute and managing director of the National Human Neural Stem Cell Resource.

“The major thing is that the footprint is much smaller than a traditional stem cell manufacturing facility, it’s all housed in one room so that keeps the cost down. The device we use to reproduce the cells is also much smaller so this set up doesn’t require multiple rooms and complex pass-throughs as you move from one room to another. All that meant the cost was only around $500,000 which is many times smaller than the more conventional facility.”

Dr. Schwartz is wasting little time putting the new facility to work. It’s already up and running and culturing cells for his work in developing a treatment for mucopolysaccharidosis (MPS-1), a rare neurodegenerative disease that usually kills children before the age of 10.

He is working on a kind of 1-2 punch approach to the disease. Using donated umbilical cord blood to help replace the child’s damaged immune system and then turning some of those blood stem cells into neural cells, the kind damaged by MPS-1, and transplanting those into the brain to repair and prevent further damage.

“This is a really interesting approach. Bone marrow transplants treat a neck down disease. Brain transplants treat a neck up disease. But conditions like MPS-1 are system wide and need both a neck down and neck up approach. Our approach could help combine those and because the cells are carefully matched also mean they won’t need to be on immune-suppressant therapy for life.”

Dr. Schwartz says animal studies using this two pronged approach have been very encouraging but he cautions there is still a lot of work to do before it would be ready for a clinical trial in people. However, if this approach is effective then it could be useful for more than just MPS-1:

“I have a high level of confidence that this will work and if it does work then we can use it in other conditions as well, such as Multiple Sclerosis. Some clinical studies show that MS patients with leukemia who got a bone marrow transplant also saw a decrease in their MS symptoms.”

Kevin McCormack