By Justin A. Varholick, Ph.D.
As we grow older theres an impending fear that we will slowly, but surely, begin to lose our vision. This slow loss of vision is clinically dubbed low vision and impacts more than 39 million Americans, costs $68 billion annually in direct health care costs, and is only growing in our population as baby boomers enter the at-risk age of 65 and older. Magnifiers can often be used to help people with acute issues of low vision, but are often inconvenient and frustrating. More serious issues of low vision such as cataracts, age-related macular degeneration, glaucoma, and diabetic retinopathy require advanced treatment and surgery. For example, cataracts can be improved or reversed by removing the cloudy lens and replacing it with an artificial one. Such surgeries are not always ideal, or convenient, and further contribute to the already hefty direct health care costs. But, a recent breakthrough by Japanese scientists, in correcting blurry vision, might reverse this bleak future.
Old cells can become new againOur story begins around the mid-20th century, in 1958. A young and aspiring scientist, named John Gurdon, was studying frogs at the University of Oxford in England. Not everyone thought Gurdon would end up actually becoming a scientist. In his early days his school master thought such a career was far-fetched for Gurdon. Indeed, he ranked last in his Biology class out of 250 students. Yet despite such poor grades, Gurdon found himself studying frogs at Oxford and earning a doctoral degree in Biology. And his studies would surprisingly lead to a breakthrough in vision, and likely many other issues in human health, like Parkinsons Disease, heart disease, and spinal cord injury.
At the time Gurdon was trying to test an age-old theory on cell development. Many scientists before him discovered that cells the smallest unit of life begin without a clear fate in the early stages of an embryo. Then as the cell develops, their fate becomes more clear. They become cells of the heart, of the brain, the kidneys, the stomach, the spinal cord, or the eyes. But they cannot go back to a time when they had no fate, or specialization. The cells can only develop in one direction, from no destiny, to a clear path, then to a mature adult cell; like one found in the heart. But you just cant take a heart cell and start the process over, maybe turning it into a brain cell.
In disagreement with this theory, Gurdon did a simple experiment. He knew that a tadpole has more adult cells than a frog egg. A tadpole has gills, a heart, eyes, etc., while a frog egg simply does not. So, he cut open the tadpole and removed a single cell from the intestine; an intestinal cell. He then cut open the intestinal cell and removed its nucleus; the seed of the cell carrying all the DNA. Very carefully, he did the same with the frog egg, and finally replaced the nucleus of the frog egg with the nucleus of the intestinal cell. According to the age-old theory, the intestinal nucleus should stop normal development of the frog egg. But thats not what happened.
Instead, the new frog egg continued to develop normally, becoming a tadpole that later became an adult frog. Gurdon thought this was unbelievably odd, and so did everyone else in science. After many more experiments doing the exact same procedure (i.e., replication), it seemed that what he saw was a real, replicable fact. For some reason the nucleus of the intestinal cell was able to reverse itself to have no fate and slowly develop into any other adult cell. The seed from the intestine somehow could become the seed of a heart, brain, kidney, or even an eye cell and of course, an intestinal cell too.
After many more experiments testing the same theory, on many more animals, it seemed the theory was true, but it just didnt work for mammals. Given that the same effect could not be repeated in a mammal, some believed this discovery did not apply to humans. But they were wrong.
The discovery of induced pluripotent stem cellsAlmost 45 years later, around the start of the millennium, Shinya Yamanaka and Kazutoshi Takahashi began running experiments that would translate Gurdons findings to humans. Born after Gurdons findings were already published and well known, Yamanaka and Takahashi grew up in a world in which the fact that old cells can become new again was widely knowna solid foundation for further hypotheses, experiments, and discovery. So, the scientists set out to do what no one had before: turn adult skin cells of mice into new cells without a clear fate.
Yamanaka, the lead investigator of the study, shared a similar early history with Gurdon. He first became a medical doctor in Japan but was frustrated by his inability to quickly remove small human tumors taking over an hour rather than the typical 10 minutes. Senior doctors gave him the nickname Jamanaka, a Japanese pun for the word jama meaning obstacle. He then found himself earning a PhD in pharmacology and becoming a post-doctoral scientist, but spent more time caring for mice than doing actual research. Frustrated again, his wife suggested he just become a practicing physician. Despite her advice, Yamanaka applied to become an Assistant Professor at Nara Institute of Science and Technology, in Japan, and won everyone over with his fantastical ideas of investigating embryonic stem cells; the cells without a clear fate.
Then the persistence paid off when Yamanaka with his assistant, Takahashi discovered how to induce adult skin cells from mice to return to an embryonic, or stem cell, state without a clear fate. They began their experiments knowing that gene transcription factors proteins that turn genes on and off were responsible for keeping embryonic cells in a state without a clear fate. They thought that by turning specific genes on and off with these factors, they could turn back time and make an adult cell embryonic again. So, they tried many different combinations of gene transcription factors and ultimately discovered that 4 specific ones were enough to induce an adult skin cell to a mouse to become an embryonic cell. Because these re-newed embryonic cells, or stem cells, originally came from adult cells they came up with a new name, induced pluripotent stem cell. Broken down, induced pluripotent stem cells means that the cell was induced to become pluripotent pluri meaning several, like plural, and potent meaning very powerful (and stem meaning to have the ability to turn into any cell in the body).
These induced pluripotent cells were thought to be very powerful indeed and scientists across the globe were excited by this great discovery. They had visions of taking a persons skin or blood, forming them into induced pluripotent cells, and then using them to grow a new liver or new parts of the brain. Laboratories across the world confirmed the results by repeating the experiment.
Human stem cells Just repeating the experiments in mice, or frogs, was not enough. They needed to begin making induced pluripotent stem cells from humans. Enter scientists from the University of Wisconsin-Madison. The lead scientist, James Thomson was already well known for deriving primate embryonic cells from rhesus monkeys in 1995 and the first human embryonic cell line in 1998. In fact, Thomsons accomplishment of isolating embryonic cells from monkeys was the first sound evidence that it was possible to do the same for humans. Such discoveries placed him on the forefront in ethical considerations for research using human embryos and the most obvious scientist to lead the path toward making induced pluripotent stem cells from humans.
Thomsons team made the first human derived induced pluripotent stem cells from adult skin, with Yamanaka as a co-scientist. They followed the same general principles set by Yamanaka, who did the procedure with mouse skin cells. Importantly to Thomson, this discovery helped to relieve some ethical controversy with using human embryos to make human stem cells. By being able to induce adult human skin to become pluripotent stem cells, much research on human stem cells could be done without human embryos albeit research with human embryos remains necessary.
Yet more important to the discussion at hand, the ability to induce human skin to become pluripotent stem cells placed us on the edge of a breakthrough. With some clinical trials in humans, the fantasy of growing a new liver, heart, or eye was more a reality than ever before.
The start of human trials In 2012, around the time both Gurdon and Yamanaka were presented with the Nobel Prize in Physiology and Medicine for their work leading to induced pluripotent stem cells, human clinical trials were beginning in Japan. The first clinical trial was for age-related macular degeneration, an eye condition leading to blindness. Unfortunately, this trial was quickly terminated when Yamanaka and his team identified small gene mutations in the transplanted induced pluripotent stem cells from the first patient. Although the procedure did cure the patient of macular degeneration, these small gene mutations worried the scientists because they could lead to tumor development.
But recently with the introduction of an inducible suicide gene that can signal cells with abnormal growth to die, human trials are starting up again. In October of 2018, Japanese scientists began trials with Parkinsons disease, a brain disease related to a shortage of neurons producing dopamine. Scientists took cells from the patients, made them into induced pluripotent stem cells, guided them to develop into dopamine producing cells, and then deposited them in the dopamine centers of the brain through surgery. The outcome is promising since similar procedures in monkeys have been successful.
Other trials in Japan have also started, including spinal cord injury and one for replacing the cornea of the eye. Early results replacing damaged corneas with induced pluripotent stem cells, thereby correcting blurry vision, were just announced at the end of August. Although it will take more patients and safety checks before all humans can get induced pluripotent cells to correct their damaged eyes, malfunctioning brains, or broken spinal cords, Takahashi the post-doctoral scientist working with Yamanaka thinks it might happen as early as 2023. So, it looks like that in our lifetime we just might be able to stay young and enjoy retirement because of great breakthroughs in animal research.Note, EuroStemCell is a great resource for learning more about the ethics and research currently being done with stem cells derived from human embryos.
Like Loading...
Related
Here is the original post:
- Stem cell transplant research breakthrough gives hope to those with blood cancer - University of Birmingham - November 29th, 2024
- Accelerating stem cell research - The University of British Columbia - November 22nd, 2024
- ISSCR Guidelines for Stem Cell Research and Clinical ... - PubMed - October 18th, 2024
- Induced pluripotent stem cell-derived mesenchymal stem cells: whether ... - October 18th, 2024
- AIIMS Bathinda Makes Breakthrough in Stem Cell Therapy Research for Heart Ailments - Elets - October 15th, 2024
- Manufactured stem cells could help to treat blood cancers in the future - October 8th, 2024
- New Facility Will Expand UC Merced's Groundbreaking Stem Cell Research - University of California, Merced - October 2nd, 2024
- Cell and Gene Therapy Research To Benefit From New Stem Cell Collection Center - Technology Networks - September 26th, 2024
- Scientists in Madison studying synthetic materials with applications in stem cell research - Wisbusiness.com - September 26th, 2024
- OpRegen (RG6501) Phase 1/2a Results to Be Featured at International Society for Stem Cell Research (ISSCR) 2024 Copenhagen International Symposium -... - September 26th, 2024
- Stem Cell Therapy Research: Creative Biolabs Advances iPSC-Derived Macrophage Solutions - openPR - September 20th, 2024
- Stem Cell Research About Stem Cells - September 20th, 2024
- $34 million for research into stem cell therapies for osteoarthritis and other conditions - BioMelbourne Network - September 18th, 2024
- $55 million for stem cell therapies, data infrastructure and research into rheumatoid arthritis - Department of Health - September 10th, 2024
- Discoveries from human stem cell research in space that are relevant to advancing cellular therapies on Earth - Nature.com - August 24th, 2024
- Stem Cell Therapy Market is expected to generate a revenue of USD 31.41 Billion by 2030, Globally, at 13.95% CAGR: Verified Market Research -... - August 16th, 2024
- Stem Cell Therapy Market is expected to generate a revenue of USD 31.41 Billion by 2030, Globally, at 13.95% CAGR: Verified Market Research - PR... - August 12th, 2024
- Advanced Parkinsons in a dish model accelerates research Harvard ... - August 10th, 2024
- Understanding Stem Cell Research | UCLA BSCRC - August 6th, 2024
- TREEFROG THERAPEUTICS PARTICIPATES IN AN INNOVATION SHOWCASE & POSTER SESSION AT THE INTERNATIONAL SOCIETY FOR STEM CELL RESEARCH (ISSCR) ANNUAL... - July 12th, 2024
- Familiar face to take over as CEO of California's stem cell research funding agency - The Business Journals - July 12th, 2024
- Factor Bioscience to Deliver Six Presentations at the International Society for Stem Cell Research (ISSCR) 2024 Annual Meeting - The Malaysian Reserve - July 12th, 2024
- Research harnesses machine learning and imaging to give insight into stem cell behavior - Medical Xpress - July 5th, 2024
- Stem Cell Research Uncovers Clues to Tissue Repair That Could Help Heal the Uterus and More - Yale School of Medicine - May 29th, 2024
- Theradaptive Secures Landmark Funding from Maryland Stem Cell Research Fund (MSCRF) to Support Human ... - PR Newswire - May 27th, 2024
- Unparalleled Research on Adipose Tissue-Derived Stem Cell Therapy Market With Current and Future Growth ... - openPR - May 15th, 2024
- 100 plus years of stem cell research20 years of ISSCR - PMC - March 26th, 2024
- Stem Cell Science and Human Research Studies Ahead of Cargo Arrival - NASA Blogs - February 18th, 2024
- Stem cell research project to launch into space - Fox Weather - January 24th, 2024
- Breakthrough in cancer research opening up stem cell therapy to more people. How you can get involved - 69News WFMZ-TV - January 20th, 2024
- Stem Cell Research Heading to the ISS on Axiom Mission 3 - ISS National Lab - January 18th, 2024
- No, Rep. Steve Scalise Didn't Vote Against Stem Cell Research From Which He Is Now Benefiting - The Dispatch - January 12th, 2024
- Applications are open for the Maryland Stem Cell Research Fund - Technical.ly - January 4th, 2024
- Global Stem Cell Therapy Market to Reach USD 928.6 Million by 2031: Says Allied Market Research - Yahoo Finance - November 19th, 2023
- Current state of stem cell-based therapies: an overview - PMC - November 3rd, 2023
- Dynamic Stem Cell Therapy Uncovers Research in Advance Regenrative Medicine - Yahoo Finance - November 3rd, 2023
- Research Fellow (Aging and Cancer Stem Cell Laboratory ... - Times Higher Education - October 15th, 2023
- Qkine Collaborates with the Cambridge Stem Cell Institute to Facilitate Same-Day Access to Key Research Products for Researchers at the Cambridge... - September 27th, 2023
- Stem cells: a comprehensive review of origins and emerging clinical ... - September 25th, 2023
- Stem Cell Research and Communicating Science | GBH - GBH News - September 20th, 2023
- Stem cell research reveals the earliest stages of a human life - SBS News - September 10th, 2023
- Stem Cell Therapy Market Size 2023 | Innovative Research Methodologies with Emerging Trends and Opportuni - Benzinga - September 10th, 2023
- Autologous Stem Cell and Non-Stem Cell Based Therapies Market Research, Current Trends, Key Industry Play - Benzinga - September 8th, 2023
- Stem Cell Therapy Market 2023 Business Statistics and Research ... - The Knox Student - August 28th, 2023
- Autologous Stem Cell Based Therapies Market Analysis, Research ... - Chatfield News-Record - July 19th, 2023
- Global Stem Cell Market Projected to Reach $14 Bn by 2028: Ken Research - Yahoo Finance - July 11th, 2023
- Theradaptive Awarded Manufacturing Assistance Grant by the Maryland Stem Cell Research Fund - Benzinga - July 10th, 2023
- Bionano Announces Presentation of OGM Utility Across Stem Cell Therapy Applications at the International Society for Stem Cell Research (ISSCR) Annual... - June 19th, 2023
- Sana Biotechnology Highlights Preclinical Data from Hypoimmune and Fusogen Platforms at the International Society for Stem Cell Research (ISSCR) 2023... - June 17th, 2023
- Induced Pluripotent Stem Cell (iPSC) Global Market Report 2023: Effective Research Programs Hold Key in Roll Out of Advanced iPSC Treatments - Yahoo... - June 17th, 2023
- Lung and heart stem cell research paves way for new COVID-19 treatments - Medical Xpress - June 14th, 2023
- Toxicology PhD student cultivating giant leaps in stem cell research ... - June 4th, 2023
- Harvard Stem Cell Institute (HSCI) - May 26th, 2023
- Findings may lead to improved insulin-secreting cells derived from stem ... - May 26th, 2023
- Cell Press: Stem Cell Reports - May 26th, 2023
- Stem cell research could enable blood to be made in other parts of the body - Medical Xpress - May 26th, 2023
- Construction of myocardial patch with mesenchymal stem cells and poly ... - May 22nd, 2023
- Cedars-Sinai to Send Stem Cells to the Space Station to Aid in the ... - May 22nd, 2023
- researchers expand human blood stem cells | Institute for Stem Cell ... - May 22nd, 2023
- A Look Inside Stem Cells Helps Create Personalized Regenerative ... - May 17th, 2023
- Exclusive Research Report on Msenchymal Stem Cell and Exosome Diagnostics and Therapies Market to Witness Comp - openPR - May 17th, 2023
- The Future of Stem Cell Research: Master of Science in ... - The Daily | Case Western Reserve University - May 10th, 2023
- Exclusive Research Report on Stem Cell Therapy for Diabetes and ... - Digital Journal - May 9th, 2023
- Aging melanocyte stem cells and gray hair | National Institutes of ... - May 5th, 2023
- Mouse hair turns gray when certain stem cells get stuck - May 5th, 2023
- Science-First Skincare Company Michal Morrison Secures Exclusive World-Wide License of Proprietary STEM6 Molecule, Supported by Over 25 Years of... - May 5th, 2023
- BioCentriq and panCELLa execute research agreement to study stem cell-derived Natural Killer cell expansi - Benzinga - May 3rd, 2023
- Hair turning gray? Study finds a stem cell 'glitch' may be the cause - May 1st, 2023
- Elevai Labs Announces Research Grant Award and Partnership to Better Characterize the 'Payload' of ELEVAI's Stem Cell-derived Exosomes - Yahoo Finance - April 27th, 2023
- Why does hair turn gray? A new study says 'stuck' stem cells may ... - NPR - April 27th, 2023
- Study advances understanding of how melanocyte stem cells work to color ... - April 21st, 2023
- Stem cell research and therapy legislation to be replaced, says ... - Bahamas Tribune - April 21st, 2023
- Stem Cell Research (journal) - Wikipedia - April 21st, 2023
- Scientists Are About to Try to Create Stem Cells in Space - April 21st, 2023
- Stem Cell Research & Therapy | Articles - BioMed Central - April 16th, 2023
- Stem Cell Junk Yards Reveal a New Clue About Aging | WIRED - April 16th, 2023
- Global Stem Cells Market Research Report 2023: Implications - April 16th, 2023
- Stem cell research can help people with hard- | EurekAlert! - April 16th, 2023
- University Of Edinburgh's stem cell research gets funding boost - India Education Diary - April 14th, 2023
- Two major stem cell research projects supported with more than ... - University of California, Santa Cruz - April 8th, 2023
Recent Comments