For a few years now, scientists at Washington University have been working on techniques to turn stem cells into pancreatic beta cells as a way of addressing insulin shortages in diabetics. After some promising recent strides, the team is now reporting another exciting breakthrough, combining this technique with the CRISPR gene-editing tool to reverse the disease in mice.

The pancreas contains what are known as beta cells, which secrete insulin as a way of tempering spikes in blood-sugar levels. But in those with diabetes, these beta cells either die off or dont function as they should, which means sufferers have to rely on diet and or regular insulin injections to manage their blood-sugar levels instead.

One of the ways scientists are working to replenish these stocks of pancreatic beta cells is by making them out of human stem cells, which are versatile, blank slate-like cells that can mature into almost any type of cell in the human body. The Washington University team has operated at the vanguard of this technology with a number of key breakthroughs, most recently with a cell implantation technique that functionally cured mice with diabetes.

The researchers are continuing to press ahead in search of new and improved methods, and this led them to the CRISPR gene-editing system, which itself has shown real promise as a tool to treat diabetes. The hope was that CRISPR could be used to correct genetic defects leading to diabetes, combining with the stem cell therapy to produce even more effective results.

As a proof of concept, the scientists took skin cells from a patient with a rare genetic type of diabetes called Wolfram syndrome, which develops during childhood and typically involves multiple insulin injections each day. These skin cells were converted into induced pluripotent stem cells, which were in turn converted into insulin-secreting beta cells. But as an additional step, CRISPR was used to correct a genetic mutation that causes Wolfram syndrome.

These edited beta cells were then pitted against non-edited beta cells from the same batch in test tube experiments and in mice with a severe type of diabetes. The edited cells proved more efficient at secreting insulin and when implanted under the skin in mice, reportedly caused the diabetes to quickly disappear. The rodents that received the unedited beta cells remained diabetic.

This is the first time CRISPR has been used to fix a patients diabetes-causing genetic defect and successfully reverse diabetes, said co-senior investigator Jeffrey R. Millman. For this study, we used cells from a patient with Wolfram syndrome because, conceptually, we knew it would be easier to correct a defect caused by a single gene. But we see this as a stepping stone toward applying gene therapy to a broader population of patients with diabetes.

The researchers are now continuing to work on improving the beta cell production technique, which in the future could involve cells taken form the blood or even urine, rather than the skin. They believe that further down the track this therapy could prove useful in treating both type 1 and type 2 diabetes, by correcting mutations that arise from genetic and environmental factors, and possibly be used to treat other conditions, as well.

We basically were able to use these cells to cure the problem, making normal beta cells by correcting this mutation, said co-senior investigator Fumihiko Urano. Its a proof of concept demonstrating that correcting gene defects that cause or contribute to diabetes in this case, in the Wolfram syndrome gene we can make beta cells that more effectively control blood sugar. Its also possible that by correcting the genetic defects in these cells, we may correct other problems Wolfram syndrome patients experience, such as visual impairment and neurodegeneration.

The research was published in the journal Science Translational Medicine.

Source: Washington University

Original post:
CRISPR combines with stem cell therapy to reverse diabetes in mice - New Atlas

CAR-T and TCR-T therapies that involve engineering a patients own immune cells with antigen-specific receptors have revolutionized blood cancer treatment. Nowscientists at Duke-NUS Medical School are exploring the possibility of turning the approach against COVID-19.

The idea of using CAR/TCR-T cell therapy has already been proposed for treating chronic viral infections such as HIV and hepatitis B. Based on previous research, Antonio Bertoletti from Duke-NUS emerging infectious diseases research program suggest these immunotherapies might also be useful in treating SARS-CoV-2, the virus causing the current pandemic.

We demonstrated that T cells can be redirected to target the coronavirus responsible for SARS. Our team has now begun exploring the potential of CAR/TCR T cell immunotherapy for controlling the COVID-19-causing virus, SARS-CoV-2, and protecting patients from its symptomatic effects, Bertoletti said in a statement.

Virtual Clinical Trials Online

This virtual event will bring together industry experts to discuss the increasing pace of pharmaceutical innovation, the need to maintain data quality and integrity as new technologies are implemented and understand regulatory challenges to ensure compliance.

These types of therapies involve modifying patients' own T cells with either a chimeric antigen receptor (CAR) or a T-cell receptor (TCR) that can recognize specific antigens associated with cancer,and then guiding the immune cells to eradicate the targets when infused back into the patients.

In a 2011 article published in the Journal of Virology, Bertoletti led a team that generated TCR-T cells that can go after SARS, another coronavirus that caused a deadly outbreak in China and other countries in late 2002 and early 2003.

The team showed that those TCR-redirected T cells displayed a functional profile similar to that of SARS-specific memory CD8 T cells from people who recovered from SARS-CoV infection. Based on the findings, the researchers suggested that TCR-T cells represent a promising prophylactic or therapeutic treatment for SARS.

RELATED:How 'duoCAR-T' cells could clear HIV and prevent resurgence of virus reservoirs

CAR-T cells have been explored in other viruses. A research team from the Albert Einstein College of Medicine and the University of Pittsburgh, for example,designed duoCAR-T cells that target three sites on the HIV envelope glycoprotein. In the lab, the cell therapy eliminated up to 99% of immune cells infected with different strains of HIV.

Despite thepromise of T-cell therapies, however, Bertoletti and colleague Anthony Tanoto Tan cautioned about potential safety concerns of using them to treat viral infections affecting vital organs. For one thing, CAR-T treatments havebeen linked to the dangerous side effect called cytokine release syndrome, in which overreactive immune cells launch an inflammatory response that can destroy organs, they said in a recent Journal of Experimental Medicine commentary. Similar cytokine storm effects have been reported in somesevere COVID-19 patients, leading to potentially life-threatening lung inflammations.

[T]he infusion ofT cells stably expressingpathogen-specific CAR/TCR poses therisk that these T cells might proliferate and wipe out all the infected cells that might be the majority of the infected organ, Bertoletti and Tanoto Tan wrote in their article.

To addressthat problem, Bertoletti and colleagues are using mRNA electroporation to engineer CAR/TCR T cells, which they say can limit their inflammatory capability and shorten the functional activity. That may offer a safer way to use engineered immune cells to treat viral diseases.

Several organizations are also working on cell therapies for COVID-19. AlloVir and Baylor College of Medicine have teamed up to develop an off-the-shelf therapy that entails exposing donor T cells to cytokines combined with viral fragments so the new cells can target the novel coronavirus. Celgene spinoff Celularity just started clinical trial of its cancer treatment CYNK-001 for COVID-19. The drugturns placental stem cells into one-size-fits-all natural killer cells.

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Scientists explore using CAR-T and other engineered immune cells to target COVID-19 - FierceBiotech

Dispositiu per a realitzar registres electrofisiolgics amb les llums LED incorporades per lus doptogentica.

Equip investigador.

Researchers from Lund University (Sweeden) and the Institute of Neurosciences of the University of Barcelona (UBNeuro) have recovered, through cell therapy, the mobility and sensibility of mice that suffered a cardiovascular accident. The results of this study were published in the journal Proceedings of the National Academy of Sciences (PNAS).

Researchers used an ischemic model of ictus in mice to which they transferred stem cells obtained from the skin of a healthy human donor. The cells were reprogramed to become neuronal progenitors of the damaged area of the brain, specifically the brain cortex. Six months after the transplant, researchers could observe how the new cells had repaired the damage that was caused by the cerebrovascular injury. In addition, the sensor and motor problems resulting from the stroke had been reversed as well.

We observed that the fibers of the cells that were put in the cortical area grew and created connections in brain areas that are far from the transplant area, notes Daniel Tornero, researcher in the Laboratory of Stem Cells and Regenerative Medicine in UBNeuro. To identify the transplanted cells, researches used different techniques that enable the monitoring so as to prove the connection in damaged circuits is right. Although there is a lot of work to do -the researcher adds-, the study sheds light on the possibility of replacing the damaged cells for new healthy cells in patients with ictus.

This is the last study of a series of three articles in which the researchers used cell therapy to work on brain healing. Previous studies showed it is possible to transplant nervous cells derived from human stem cells or reprogrammed cells in the brain of mice affected by cardiovascular injuries. However, researchers did not know whether the transformed cells could create new connections in the mice brains and restore the movement and feelings of touch.

The next step is to understand how the transplant affects intellectual functions such as memory, and the potential adverse effects, concludes Tornero.

Article reference:

S. Palma-Tortosa, D. l Tornero, M. Grnning Hansen, E. Monni, M. Hajy, S. Kartsivadze, S. Aktay, O. Tsupykov, M. Parmar, K. Deisseroth, G. Skibo, O. Lindvall, y Z. Kokaia. Activity in grafted human iPS cellderived corticalneurons integrated in stroke-injured rat brain regulatesmotor behavior. Proceedings of the National Academy of Sciences (PNAS). Doi: doi: 10.1073/pnas.2000690117

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Researchers use cell therapy to recover damaged brain areas in mice that suffered - Mirage News

Despite centuries-long efforts to develop cures for cancer, various forms of the disease will kill about 630,000 people in the U.S. in 2020. But hopes are rising for cell therapies sometimes called living medicines that can boost and adapt the natural cancer-fighting potential of the immune system in ways that conventional cancer treatments cannot match.

UC San Francisco researchers now have reported a new method to design and test cell therapies, one they expect will speed the development of new life-saving treatments not only for cancer, but for other diseases, too.

Cell therapy for cancer is a type of immunotherapy. Immune-system cells known as T cells are isolated from a patients blood and genetically modified in the lab, inserting or removing genes so the cells will better recognize and destroy tumors. These modified T-cells are grown in culture until they number in the hundreds of millions, and are then infused back into the patient through an IV drip.

One form of cell therapy, known as CAR-T-cell therapy, is already approved for certain blood cancers, but so far cell therapies have not been effective against the solid tumors that affect the breast, colon, brain, lung, and other tissues.

In 2018, a UCSF team led by immunologist Alex Marson, MD, PhD, along with Theo Roth, an MD/PhD student in the UCSF Medical Scientist Training Program, developed a breakthroughtechnique in which they used pulses of electricity (a method called electroporation) to enable CRISPR gene-targeting technology to quickly and efficiently reprogram T-cells with new functions.

Now, in a study published April 16, 2020, in Cell, the team hasadvanced this technique to power a high-throughput platform to evaluate the specificity and potency of many different potential cell therapies simultaneously comparable to the approach already widely used in industry to quickly screen large batches of small molecules to assess whether they would make effective drugs.

The UCSF researchers evaluated a library of 36 different DNA sequences, a selection based on educated guesses about which bits of genetic material, when spliced into T cells, might alter cell function to better fight cancer. They inserted the different sequences into different T cells to compare their best guesses head to head in the lab.

Rather than pursuing one educated guess at a time, we wanted a systematic way to compare different potential therapeutic edits head to head, said Marson, who serves as scientific director of biomedicine at the UCSF-UC Berkeley Innovative Genomics Institute (IGI) and is a Chan Zuckerberg Biohub Investigator. The ability to iterate fast and test different candidates against each other is what the field needs to move forward and have a discovery engine for next-generation cell therapies.

Many solid tumors express proteins that shield them from T cell attacks, so the researchers evaluated not only the modified cells ability to find cancer cells, but also their ability to accumulate robustly within tumors. Using a distinctive DNA barcode to track the modified T cells, the researchers raced them against one another in lab dishes and in vivo cancer models. This allowed them to identify specific gene modifications that give T cells the best ability to kill off solid-tumor cells in a lab dish and also more effectively fight a type of human skin cancer grown in mice.

Their new methods also enable researchers to measure specific patterns of gene activation within individual T cells to gain insight into how cellular functions have changed in the modified cells that fare best against tumors.

We now are working to further scale up and optimize this screening platform, said Roth, who with Marson is a co-founder of Arsenal Biosciences, a company funded in part by the Parker Institute for Cancer Immunotherapy that is focused on producing and testing new cell therapies. We believe this cell therapy development platform will make it possible for academics and industry to begin generating all sorts of genetically programed T cells targeted to specific cancers as well as other medical applications.

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CRISPR-Based 'Discovery Engine' for New Cell Therapies to Advance Cancer Treatments - UCSF News Services

The rapid growth of biopharma is causing a shift to a new paradigm for the drug development and delivery model. In the same manner that the personal computing industry grew and developed business models that fit the way products were sourced, constructed and delivered, a business model for biopharma is taking shape.

Jeff Galvin, CEO of American Gene Technologies (AGT), had 30 years of business and entrepreneurial experience in Silicon Valley during the formative years of the personal computing and internet era. He left retirement as an Angel Investor in real estate and high tech in 2008 to found AGT and lead it in developing a bank for Lentiviral vectors with different characteristics for use with its gene delivery platform.

The use of these vectors with this platform will save time and money in drug development, Galvin said as he shared his vision for the biopharma industry with BioSpace.

The Personal Computing Industry as a Model

In the early days of the personal computing industry, a computer company was responsible for its product from start to finish. This could not only include hardware and software but peripherals as well. As the industry grew and matured, Galvin explained, other industries grew up around the personal computer industry. These were not mere opportunities to outsource; these were companies acting with their own plans and interests in mind. The result of this was the development of software by vendors having no more to do with a computer manufacturer than the ability to code in a language that the computer would recognize.

This autonomy made it possible for companies to specialize in certain types of software, even to the point of supporting one specific app. The need to save data and put new software onto a computer led to an industry based on physical storage media. As computer technology grew, the precise product - floppy to CD and onward - evolved. Over time, it has led to cloud-based computing in which the software no longer comes on a physical medium, says Galvin. This uncoupling of software and peripherals from the computer hardware itself has given rise to exponential growth in applications and the ability to use computers to solve myriad problems.

American Gene Technology (AGT) Offers a Delivery System

Similarly, as the gene and cell therapy industries grow, companies that specialize in one aspect of the drug development process or in one application will be able to focus on that one part. As long as what is developed will work with the human body, genes and cell therapy can be used to alter the DNA. For AGT, this means collaborating with researchers who are looking for a delivery system for the innovative treatments they develop.

Galvin explains, AGTs platform is a broad set of reusable components and fundamental innovations on the use of any or all viral vectors to reliably deliver genetic changes to cells that are safe, predictable, and that maintain therapeutic expression for the duration necessary for the mission of mitigating the disease state. The viral vectors are the diskettes that carry the software updates to your DNA, the operating system, of your organic computer, aka the human cell. Rather than machines and code, AGT delivery platform makes it possible to use the human body and its genes to treat disease.

AGT began with lentiviruses because, Galvin explains, it happens to be what we believed was the right vector delivery on our three lead programs of HIV, phenylketonuria (PKU), and cancer. This was because the lentivirus matched the attributes we were looking for in terms of cargo space for genetic constructs.

With the ability to deliver the genes needed to modify specific cells types or tissue, AGT is able to provide this capability for a range of therapies. Currently, AGT is working to cure HIV through the use of its lentivirus delivery platform. With a viral vector as the diskette used to load the genetic construct into that vector as the software, the virus will do the work of delivering the critical change to a cell.

The Future

AGT views itself as a vector agnostic delivery company, Galvin explained. In the future, they will work with whichever delivery vector is needed. As delivery vectors improve, AGT will have the capability of combining more of their components on a single vector, resulting in the opportunity to address increasingly complex diseases.

We will look to partners that pioneer new methods of modifying DNA in cells (even CRISPR when it becomes as reliable and safe as lentivirus), and we will continue to revise and optimize our drugs to utilize the capabilities that those partners develop, Galvin said.

To date, AGT has seen that each time we start a new drug, we find that our previous R&D yielded components and techniques that provide a base, the starting point, that is up to 80% of the next drug candidate, Galvin said.

This efficiency is AGTs strategy for remaining competitive in this disruptive industry. It is also necessary if the benefits of the gene and cell therapy revolution are to achieve the reductions in cost necessary to reach the greatest number of patients in need.

Galvin believes the evolution of the gene and cell therapy technology and industry will track closely with the evolution of the computer industry. His vision is an encouraging one for the rest of us. If the comparison holds, well see that as companies find their place in the industry and hone their offering, the advances to be made will be rapid and significant. The result will be improved treatments, along with treatments for diseases that are currently considered incurable.

-Please click here for more information on our contributing writer,Gina Hagler.

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AGT CEO Jeff Galvin on the Future of the Gene and Cell Therapy Industry - BioSpace

CAMBRIDGE, Mass., April 23, 2020 (GLOBE NEWSWIRE) -- Genocea Biosciences, Inc. (NASDAQ: GNCA), a biopharmaceutical company developing next-generation neoantigen immunotherapies, will host its first quarter 2020 financial results and corporate update conference call and live audio webcast onThursday, April 30that 8:30 a.m. EDT. Interested participants may access the conference call by dialing (844) 826-0619 (domestic) or (315) 625-6883 (international) and referring to conference ID number 4855738. To join the live webcast, please visit the presentation page of the investor relations section of the Genocea website athttps://ir.genocea.com/events-and-presentations. A webcast replay will be available on the Genocea website beginning approximately two hours after the event and will be archived for 90 days.

Additionally, Genocea will host a virtual KOL symposium with a live Q&A providing a brief review of the current T cell therapy landscape including the evolution of TIL and TCR therapy utility, and the need for new approaches to better patient outcomes on Tuesday, May 12th at 12 p.m. EDT. Members of the Genocea management team will also provide an overview of the development of GEN-011, a potential best-in-class solid tumor adoptive T cell therapy. More details will follow on accessing the virtual KOL symposium.

About Genocea Biosciences, Inc.Genoceas mission is to conquer cancer by developing personalized cancer immunotherapies in multiple tumor types. Our unique ATLAS platform comprehensively profiles each patients T cell responses to potential targets, or antigens, on the tumor. ATLAS enables us to optimize the neoantigens for inclusion in our immunotherapies and exclude inhibitory antigens that can exert an immunosuppressive effect. We are advancing two ATLAS-enabled programs: GEN-009, our neoantigen vaccine for which we are conducting a Phase 1/2a clinical trial and expect preliminary clinical results in Q2/Q3 2020, and GEN-011, our neoantigen-specific cell therapy using T cells derived from peripheral blood, for which we intend to file an Investigational New Drug Application in the second quarter of 2020. To learn more, please visit http://www.genocea.com.

Forward-Looking StatementsThis press release includes forward-looking statements, including statements relating to GEN-009 and GEN-011, within the meaning of the Private Securities Litigation Reform Act. Such forward-looking statements are subject to risks and uncertainties that could cause actual results to differ materially from those expressed or implied in such statements. Genocea cautions that these forward-looking statements are subject to numerous assumptions, risks and uncertainties that change over time. Applicable risks and uncertainties include those identified under the heading "Risk Factors" included in Genocea's Annual Report on Form 10-K for the year ended December 31, 2019 and any subsequent SEC filings. These forward-looking statements speak only as of the date of this press release and Genocea assumes no duty to update forward-looking statements, except as may be required by law.

Investor Contact:Dan Ferry617-430-7576daniel@lifesciadvisors.com

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Genocea to Host First Quarter 2020 Corporate Update Conference Call & WebcastVirtual KOL symposium scheduled for May 12th to review GEN-011 ...

Mrinsights.bizhas published a new report titled GlobalAnimal Stem Cell TherapyMarketGrowth 2020-2025 which comprises new statistical data on the changing market scenario and initial and future assessment of the market. The report covers a wide range of business aspects global Animal Stem Cell Therapy trends, future forecasts, growth opportunities, key end-user industries, and market players. The report analyzes the recent developments, investment opportunities, and probable threats in the market. It closely looks at the markets all-purpose evaluation and depicts the important data associated with the global market.

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Global Animal Stem Cell Therapy Market 2020 Future Scenario, Industry Growth Insights and Production Analysis 2025 - Bandera County Courier

The Animal Stem Cell Therapy report provides independent information about the Animal Stem Cell Therapy industry supported by extensive research on factors such as industry segments size & trends, inhibitors, dynamics, drivers, opportunities & challenges, environment & policy, cost overview, porters five force analysis, and key companies profiles including business overview and recent development.

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Scope of Animal Stem Cell Therapy Market: Products in the Animal Stem Cell Therapy classification furnish clients with assets to get ready for tests, tests, and evaluations.

Animal Stem Cell Therapy Market Report Covers the Following Segments:

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Animal Stem Cell Therapy Market Is Set To Experience Revolutionary Growth By 2025 - Cole of Duty

Pluristem Therapeutics or PLX cell therapyuses placentas to grow smart cells, and programs them to secrete therapeutic proteins in the bodies of sick people. It has just treated its first American COVID-19 patient after treating seven Israelis. The patients were suffering from acute respiratory failure and inflammatory complications associated with Covid-19. Now, this theraphy is being touted as a possible 'cure'' for the deadly coronavirus with scientisst conducting varied researches on the same. In an exclusive interaction with India TV, doctors from India and abroadcame together for discussing about how effective can cell therapy be in treating coronavirus. Dr Solomon from Israel, Dr Anil Kaul from the US, DrSanjeev Chaubey from Shanghai and Dr Padma Srivastv and Dr Harsh Mahajan from India threw light upon the stem cell therapy and the possibility of incorporating the same in treating COVID-19 pateints.

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How effective is PLX cell therapy in treating coronavirus? Experts answer all queries and more - India TV News

Mogrify Ltd (Mogrify), a UK company aiming to transform the development of cell therapies by the systematic discovery of novel cell conversions, and Sangamo Therapeutics (Sangamo), a genomic medicine company, have announced that they have executed a collaboration and exclusive license agreement for Sangamo to develop allogeneic cell therapies from Mogrifys proprietary induced pluripotent stem cells (iPSCs) and embryonic stem cells (ESCs) and Sangamos zinc finger protein (ZFP) gene-engineered chimeric antigen receptor regulatory T cell (CAR-Treg) technology.

Mogrify is delighted to announce its second commercial deal with a US biopharma and the first in the exciting field of T cell immunotherapy, said Dr. Darrin M. Disley OBE, CEO, Mogrify. The combination of Mogrifys proprietary systematic cell conversion technology and Sangamos regulatory T cell platform and proprietary ZFP platform is a natural fit. Sangamo is at the forefront of the development of a world-class engineered ZFP genome editing platform and we are very happy to be partnering with such an innovative company.

This license agreement provides Sangamo with access to Mogrifys cell conversion technology, which will diversify our options as we develop off-the-shelf allogeneic CAR-Treg cell therapies, said Jason Fontenot, SVP, Head of Cell Therapy at Sangamo. We expect this collaboration to accelerate our development of scalable and accessible CAR-Treg cell therapies, so that we can potentially deliver treatments to patients with inflammatory and autoimmune diseases more rapidly.

Mogrifys technology enables the transformation of any human cell type into any other human cell type. This transformation is achieved using transcription factors or small molecules identified using proprietary big data technologies. iPSCs and ESCs provide an evergreen starting material for the generation of Tregs, and facilitate more complex engineering and greater manufacturing scalability, potentially enabling the resulting therapies to be more cost-effective and thus more accessible to larger patient populations.

Under the terms of the agreement, Mogrify will be responsible for the discovery and optimization of the cell conversion technology from iPSCs or ESCs to regulatory T cells, and Sangamo will be granted exclusive rights to use Mogrifys technology to create Tregs from iPSCs or ESCs. Sangamo expects to then use its ZFP gene-engineering technology and therapeutic development capabilities to transform these Tregs into novel off-the-shelf allogeneic CAR-Treg cell therapy candidates and hopes to take them through clinical development through to registration for the treatment of inflammatory and autoimmune diseases.

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Mogrify and Sangamo announce collaboration and exclusive license agreement for Mogrify's iPSC- and ESC-derived regulatory T cells - SelectScience