Stem cell image of the week:  Immature human eggs (pink) were created by Japanese researchers using stem cells that were derived from blood cells.

Photo Courtesy of Saitou Lab

A team of Japanese scientists say they have taken an important step toward creating human eggs in a lab dish.

Their work, which was reported Thursday in the journal Science, outlined their research and explained how they were able to turn human blood cells into stem cells, which they then transformed into very immature human eggs.

They say the eggs are too immature to be fertilized or make a baby. And much more research would be needed to create eggs that could be useful, and safe for human reproduction. But they believe the technique could someday help millions of people suffering from infertility.

In their paper, the Japanese scientists say the next step will be to try to make mature human eggs and produce human sperm this way.

“It’s the beginning of a paradigm change,” says Kyle Orwig, a professor in the department of obstetrics, gynecology and reproductive sciences at the University of Pittsburgh School of Medicine.

In addition to helping infertile people, such a development could enable same sex couples to have babies with sperm and eggs made from their own skin cells.

But such a possibility would also have much broader implications, say others following the field.

Newly discovered stem cells may help heal broken bones and arthritic joints. (Todd Dubnicoff)

Oh, to be a newt. This semi-aquatic salamander is able to regenerate an entire limb after injury. The regenerative ability of our human bodies just doesn’t measure up: we can heal a bone fracture though that ability weakens as we age, and some bone fractures called nonunions are unable to heal. And we have no ability to regrow lost cartilage leaving 75 million Americans suffering with painful, debilitating arthritis.

A small bone structure arising from the human skeletal stem cell contains cartilage (blue), bone marrow (brown) and bone (yellow). Image credit: Longaker and Chan labs, Stanford University.

CIRM-funded research published this week in Cell may one day give doctors a leg up on treating bone-related disease and injury. The Stanford team behind the study reports that they’ve identified a stem cell that gives the three main components of our skeleton: the outer bone, the spongy interior and cartilage that provides cushion in our joints. The scientists showed that these skeletal stem cells are separate from mesenchymal stem cells which can also specialize, or differentiate, into skeletal tissues as well as fat and muscle. One of the lead authors, Dr. Charles Chan, PhD, explained the important distinction between the two cell types in a press release:

“Mesenchymal stem cells are loosely characterized and likely to include many populations of cells, each of which may respond differently and unpredictably to differentiation signals. In contrast, the skeletal stem cell we’ve identified possesses all of the hallmark qualities of true, multipotential, self-renewing, tissue-specific stem cells. They are restricted in terms of their fate potential to just skeletal tissues, which is likely to make them much more clinically useful.”

The researchers located skeletal stem cells at the end of developing bone and found them in increasing numbers at the site of healing broken bones. The scientists were also able to derive them by reprogramming readily available human fat cells as well as embryonic stem cell-like induced pluripotent stem cells (iPSCs). With these skeletal stem cells now in hand, the team is excited with the prospect of combining cartilage-repair surgeries with an injection of the stem cells to boost healing. Senior author Michael Longaker envisions the impact of such therapies on healthcare in the U.S.:

“I would hope that, within the next decade or so, this cell source will be a game-changer in the field of arthroscopic and regenerative medicine. The United States has a rapidly aging population that undergoes almost 2 million joint replacements each year. If we can use this stem cell for relatively noninvasive therapies, it could be a dream come true.”

Cincinnati Children’s researchers report progress growing a human esophagus in a lab (Adonica Shaw) 

A confocal microscopic image shows a two-month-old human esophageal organoid bioengineered by Cincinnati Children’s Hospital researchers from pluripotent stem cells.      Image courtesy of Cincinnati Children’s Hospital

Scientists from Cincinnati Children’s Center for Stem Cell and Organoid Medicine (CuSTOM) have successfully grown human esophageal tissue entirely from pluripotent stem cells (PSCs).

Their research, which was published in the journal Cell Stem Cell, is the latest advancement from (CuSTOM). They believe it will open the door for other scientists  to form any tissue type in the body from stem cells.

The center is developing new ways to study birth defects and diseases that affect millions of people with gastrointestinal disorders, such as gastric reflux, and this research is a milestone for them.

“Disorders of the esophagus and trachea are prevalent enough in people that organoid models of human esophagus could be greatly beneficial. In addition to being a new model to study birth defects like esophageal atresia, the organoids can be used to study diseases like eosinophilic esophagitis and Barrett’s metaplasia, or to bioengineer genetically matched esophageal tissue for individual patients, ” said Jim Wells, PhD, chief scientific officer at CuSTOM and study lead investigator.

The resulting human esophageal organoids were fully formed and grew to a length of about 300-800 micrometers in about two months. Compared biochemically with esophageal tissues from patient biopsies, the bioengineered tissues were similar.

The research team plans to further the technology’s therapeutic potential through projects including using the organoids to examine the progression of specific diseases and congenital defects affecting the esophagus.

Stem cell image of the week:  New Research out of the Salk Institute could bring us closer to reprogramming stem cells without taking them out of the body (Adonica Shaw)

Our stem cell image of the week could be a step towards reprogramming cells in vivo.

The image represents the first proof of principle for the successful regeneration of a functional organ (the skin) inside a mammal, by a technique known as AAV-based in vivo reprogramming. Epithelial (skin) tissues were generated by converting one cell type (red: mesenchymal cells) to another (green: basal keratinocytes) within a large ulcer in a laboratory mouse model.

Photo courtesy of the Salk Institute

In large patches of ulcerous skin, surviving cells prioritize inflammation and wound closure. That’s what they’re programmed to do. Cells, on the other hand, can be reprogrammed in living tissue, wounded tissue, to expedite healing.

A group of scientists at the Salk Institute developed a new approach to cellular reprogramming. They found a way to directly convert the cells in an open wound into new skin cells. Their findings were published on Wednesday in Nature.

Reprogramming wound-resident cells could be useful for healing skin damage, countering the effects of aging, and helping us to better understand skin cancer. It could also supplant plastic surgery and the application of skin grafts as a way to treat large cutaneous ulcers, including those seen in people with severe burns, bedsores, or chronic diseases such as diabetes.

When an ulcer is especially large, it can be difficult for surgeons to graft enough skin. In these cases, researchers can isolate skin stem cells from a patient, grow them in the lab and transplant them back into the patient. However, such a procedure requires an extensive amount of time, which may put the patient’s life at risk and is sometimes not effective.

 “Our observations constitute an initial proof of principle for in vivo regeneration of an entire three-dimensional tissue like the skin, not just individual cell types as previously shown,” says Dr. Izpisua Belmonte. “This knowledge might not only be useful for enhancing skin repair but could also serve to guide in vivo regenerative strategies in other human pathological situations, as well as during aging, in which tissue repair is impaired.”

Positive news from a CIRM-funded clinical trial targeting a deadly blood cancer. (Kevin McCormack)  Multiple myeloma is a type of blood cancer where certain cells in the bone marrow grow out of control, crowding out the healthy cells and forming tumors. There is no cure but there are many treatments that can slow down or even halt the progression. Over time, however, many of those treatments lose their effectiveness and the cancer returns. Now a new CIRM-funded clinical trial targeting this kind of relapsing multiple myeloma is showing promise.

The trial, by Poseida Therapeutics, takes an immunotherapy approach that uses the patient’s own engineered immune system T cells to seek and destroy the myeloma cells. This product, called P-BCMA-101, is a stem cell memory chimeric antigen receptor T-cell (CAR-T).

In the first eleven patients treated there were no serious side effects and only one patient had a suspected case of cytokine release syndrome. That’s where large amounts of cytokines, immune substances, are rapidly released into the body causing fever, nausea, rapid heartbeat etc. However, even in this patient the symptoms quickly passed.

In a news release, Eric Ostertag, the CEO of Poseida said that even though the goal of this Phase 1 study was just to make sure it was safe and to identify the best dose to give patients, they have already seen a very good partial response in some patients.

“We believe our advantages of a purified product, where all cells express the CAR molecule, and a product with high levels of stem cell memory T cells, producing a more gradual and prolonged immune response against tumor cells, provide a significantly better therapeutic index when compared with other CAR-T therapeutics. We are also encouraged that P-BCMA-101 is demonstrating significant efficacy even at doses that have been ineffective for other anti-BCMA CAR-T therapies and that our response rates continue to improve as the dose increases.”

The clinical trial will eventually treat 40 patients with relapsing or remitting multiple myeloma and we will bring more results as they become available.

Techniques used in ecology help rewrite basic fact about blood stem cells (Todd Dubnicoff) It’s been over half a century since the first blood stem cell transplantation was performed. And yet, some fundamental facts about these cells – which give rise to all the cell types of our blood – have remained cloudy, like the number of blood stem cells present in the human body. This week, researchers at Wellcome Sanger Institute and Wellcome – MRC Cambridge Stem Cell Institute report that they’ve cleared up this long-lasting question.

A blood cell colony grown from a single cell isolated from a 59-year-old man. Image Credit: Mairi Shepherd, Kent Lab

And the results were surprising. Using whole genome DNA sequencing and techniques found in ecology for tracking population sizes, the team determined that a healthy adult has between 50,000 and 200,000 blood stem cells at any given time. That’s about 10 times more than what was previously thought.

Dr. David Kent, a co-senior author on the report, described the implications of this discovery in a press release:

“This new approach is hugely flexible. Not only can we measure how many stem cells exist, we can also see how related they are to each other and what types of blood cells they produce. Applying this technique to samples from patients with blood cancers, we should now be able to learn how single cells outcompete normal cells to expand their numbers and drive a cancer.”

The study was published in Nature.