Gladstone Institutes

Gladstone Institutes
Established 1979
President R. Sanders Williams
Faculty 27
Staff 450
Budget $80 million
Location 1650 Owens St., San Francisco, CA
Website http://gladstoneinstitutes.org/

The Gladstone Institutes is an independent and nonprofit biomedical research organization whose focus is to better understand, prevent, treat and cure cardiovascular, viral and neurological conditions such as heart failure, HIV/AIDS and Alzheimer's disease.[1] Gladstone researchers study these diseases using techniques of basic and translational science.[2] Another focus at Gladstone is building on the breakthrough development of induced pluripotent stem cell technology by one of its investigators, 2012 Nobel Laureate Shinya Yamanaka, to improve drug discovery, personalized medicine and tissue regeneration.[3]

Founded in 1979, Gladstone is affiliated with the University of California, San Francisco (UCSF) and is located in San Francisco, adjacent to UCSF’s Mission Bay campus. Approximately 450 staff members—including more than 300 scientists—work at Gladstone.[4]

History

The Gladstone Institutes was founded in 1979 as a research and training facility housed at San Francisco General Hospital. Under the leadership of Robert Mahley[5]—a leading cardiovascular scientist recruited from the National Institutes of Health[6]—the J. David Gladstone Institutes was launched with a trust valued at $8 million from the late commercial real estate developer, J. David Gladstone.[7]

In 1991 Gladstone expanded its focus to include virology and immunology in response to the growing HIV/AIDS crisis.[4]

In 1998 Gladstone founded a third institute dedicated to studying neurological diseases.[4]

In 2004 the Gladstone Institutes moved to the new facility that it built on San Francisco’s Mission Bay campus.[8] Two years later Gladstone founded a center dedicated to translating its biological discoveries into therapies.[9] Three years later and together with Taube Philanthropies and the Koret Foundation, Gladstone founded the Taube-Koret Center for Huntington's Disease Research,[10] as a direct outgrowth of the growing focus on translational science to study and find treatments for disease.

In 2010, Dr. Mahley stepped down in order to return to more active research. That same year, R. Sanders “Sandy” Williams left Duke University, where he had been Dean of the School of Medicine—as well as Senior Vice Chancellor and Senior Advisor for International Strategy—to become Gladstone’s new president.[11]

The following year, the S.D. Bechtel, Jr. Foundation helped launch the Center for Comprehensive Alzheimer's Disease Research, while the Roddenberry Foundation helped launch the Roddenberry Stem Cell Center for Biology and Medicine.[3] Also in 2011, the independent and philanthropic Gladstone Foundation formed with the mission of expanding the financial resources that drive Gladstone’s mission.

Research Programs

Gladstone scientists focus on three main disease areas: cardiovascular disease, neurological disease and viral/immunological disease. Scientists working in all three disease areas use stem cell technology to advance the understanding, prevention, treatment and cure of disease.

Cardiovascular Disease

Gladstone cardiovascular scientists research the spectrum of cardiovascular disease—including congenital heart disease, congestive heart failure and related metabolic diseases such as diabetes. Scientists utilize developmental, chemical and stem cell biology approaches, as well as genomics techniques.

Current research programs include:[4]

Virology and Immunology

Virology and immunology research at Gladstone is focused primarily on three urgent challenges related to the HIV/AIDS epidemic: preventing viral transmission of HIV with drugs or a vaccine for those at risk of coming in contact with the virus, curing the millions of people who already live with HIV and restoring a normal lifespan to those who are HIV-positive—but who are dying earlier than their uninfected counterparts from diseases of aging.

In addition, the group studies hepatitis C, HTLV and the immunology of viral infections.

Current research programs include:[14]

Neurological Disease

Research at Gladstone focuses on major neurological diseases including: Alzheimer's disease, Parkinson's disease, frontotemporal dementia (FTD), Huntington's disease, amyotrophic lateral sclerosis (ALS, or Lou Gehrig’s disease) and multiple sclerosis. This research incorporates animal models, electrophysiology, behavioral testing and automated high-throughput analyses. In addition, Gladstone investigators seek to accelerate the movement of basic science discoveries into clinical trials with efforts to bridge the so-called “Valley of Death.” The research features an emphasis on the “common threads” that link the various diseases and treatments for them.

Current research programs include:[4]

Stem Cell Technology

Many research areas build upon the stem cell work of Gladstone Senior Investigator Shinya Yamanaka. After completing his postdoctoral training at Gladstone, Yamanaka discovered induced pluripotent stem cell technology, by which ordinary differentiated adult cells (such as fibroblasts from skin) can be "reprogrammed" into a pluripotent state — i.e., a state similar to embryonic stem cells, which are capable of developing into virtually any cell type in the human body. His discovery of induced pluripotent stem cells, or iPS cells, has since revolutionized the fields of developmental biology, stem cell research and both personalized and regenerative medicine.[27] In 2012 Yamanaka was awarded the Nobel Prize in Physiology or Medicine.[28]

Since Yamanaka's 2006 discovery, scientists have made many advances in iPS technology and continue to conduct research in several areas of stem cell biology.

Current research programs include:[4]

Translational Research

The Gladstone Center for Translational Research facilitates interactions between Gladstone scientists and the biomedical industry—including venture capitalists, biotech firms and large corporations. The Center’s primary goal is to translate the results of Gladstone’s basic science into therapeutics that help patients with cardiovascular, viral or neurological diseases.

Distinguished Findings by Gladstone Investigators

Robert W. Mahley—Established the importance of the protein apoE while working at the National Institutes of Health (NIH), later making significant contributions to science’s understanding of the critical role that apoE plays in heart disease and Alzheimer's disease.[6]

R. Sanders “Sandy” Williams—While at Duke University, discovered key genes, proteins, and pathways involved in the development and proliferation of cardiac and skeletal muscle cells—giving researchers important insight into how a heart becomes a heart.[11]

Deepak Srivastava—Regenerated the damaged hearts of mice by transforming cells that normally form scar tissue after a heart attack into beating heart-muscle cells. This discovery, now moving forward with pre-clinical trials, could one day change the way doctors treat heart attacks.[13]

Shinya Yamanaka—Awarded the 2012 Nobel Prize in Physiology or Medicine for his discovery of how to transform ordinary adult skin cells into induced pluripotent stem cells (iPS cells) that, like embryonic stem cells, can then develop into other cell types.[31] Since he first announced this research in 2006 (in mice) and in 2007 (in humans), this breakthrough has since revolutionized the fields of cell biology and stem cell research, opening promising new prospects for the future of both personalized and regenerative medicine.[27]

Sheng Ding—Discovered multiple “small molecules” or chemical compounds that can be used to generate iPS cells in the place of traditional reprogramming factors. Also made progress in the area of “partial reprogramming” in which cells are converted only part way to the pluripotent state before being instructed to become another cell type—a faster process that reduces the risk of these cells forming tumors as a result of the reprogramming process. These discoveries are a significant step towards better and more efficient human models for drug testing and development.[29]

Warner C. Greene—Provided insight into precisely how HIV attacks the human immune system and how small fibrils found in semen enhance the ability of HIV to infect new cells—paving the way for the development of new ways to prevent the spread of the virus.[4]

Robert M. Grant—Led the global study, referred to as iPrEx, which in 2010 showed how an existing HIV/AIDS medication called Truvada could effectively be used to prevent the transmission of HIV in those likely to be exposed to the virus. This study is currently in Phase-III clinical trials. In July, the FDA approved Truvada as an HIV-preventative.[15]

Lennart Mucke—Discovered key mechanisms that underlie the specific dysfunctions in the brains of patients suffering from Alzheimer's disease, and helped identify novel therapeutic strategies to block these disease-causing mechanisms.[20]

Steve Finkbeiner—Developed an automated, high-resolution imaging system called a ‘robotic microscope,’ and which can track neurons over long time periods of time. This invention has significantly improved our understanding of how neurodegenerative conditions such as Huntington’s destroy neurons.[23]

Katerina Akassoglou—Showed that the blood protein called fibrinogen plays a role in diseases of the central nervous system. Her studies suggest that molecular interactions between blood and the brain can be targets for therapeutic intervention in neurological diseases such as multiple sclerosis.[25]

Katherine Pollard—Discovered short sequences of human DNA that have evolved rapidly since the human and ape lines diverged millions of years ago. Most of these fast-evolving sequences are genes that actually control other genes nearby. Many are located near genes that are active in the brain, and one appears to have a role in how the wrist and thumb develop in the fetus. These discoveries give us new insight not only into the evolutionary history of our species, but also into how genes control embryonic development—which gets us a step further to unraveling how to interrupt congenital defects.[32]

Yadong Huang—Transformed skin cells into cells that develop on their own into an interconnected, functional network of brain cells. Such a transformation of cells may lead to better models for studying disease mechanisms and for testing drugs for devastating neurodegenerative conditions such as Alzheimer's disease.[30]

References

  1. 1.0 1.1 Gladstone boosts funding, science and fame, San Francisco Business Times
  2. http://www.bizjournals.com/sanfrancisco/blog/biotech/2012/07/gladstone-roddenberry-hiv-alzheimers.html
  3. 3.0 3.1 Gladstone to announce new stem cell center, San Francisco Chronicle
  4. 4.0 4.1 4.2 4.3 4.4 4.5 4.6 Official Website
  5. Profile, J. David Gladstone Institutes, San Francisco Business Times
  6. 6.0 6.1 6.2 Profile of Robert W. Mahley, Proceedings of the National Academy of Sciences
  7. "The Gladstone Story". The Gladstone Institutes. Retrieved 27 November 2014.
  8. Boost for biotech in SF, San Francisco Chronicle
  9. http://gladstoneinstitutes.org/our-science/translational-research
  10. http://gladstoneinstitutes.org/our-science/translational-research/centers
  11. 11.0 11.1 Williams spins science into fundraising gold, San Francisco Business Times
  12. Discovery in SF could unlock origins of heart deficits, KGO-TV
  13. 13.0 13.1 13.2 Reversing a heart attack: scientists reprogram scar tissue into working muscle, Scientific American
  14. http://gladstoneinstitutes.org/node/11375
  15. 15.0 15.1 FDA panel backs drug to prevent HIV infection, CBS Evening News
  16. Doitsh G. et al Cell (2010) Abortive HIV Infection Mediates CD4 T Cell Depletion and Inflammation in Human Lymphoid Tissue
  17. Doitsh G. et al Nature (2013) Cell death by pyroptosis drives CD4 T-cell depletion in HIV-1 infection
  18. Monroe KM et al Science (2013) IFI16 DNA Sensor Is Required for Death of Lymphoid CD4 T Cells Abortively Infected with HIV
  19. Scientists Discover How Key Immune Cells Die During HIV Infection and Identify Potential Drug to Block AIDS
  20. 20.0 20.1 Gladstone researchers find epilepsy drug that may work for Alzheimer's patients, San Francisco Business Times
  21. Studies tie abnormal protein build-up to dementia, New York Times
  22. Gladstone scientists identify role of key protein in ALS and frontotemporal dementia, PhysOrg
  23. 23.0 23.1 Robotic microscope: a tinker's breakthrough, San Francisco Chronicle
  24. Protein that controls movement does the opposite in Parkinson's, MSN Health
  25. 25.0 25.1 NIH-funded Researchers Show Possible Trigger for MS Nerve Damage , ScienceNewsLine
  26. Researchers Lasso TDP-43 With RNA Lariats, Alzheimer's Research Forum
  27. 27.0 27.1 Profile of Shinya Yamanaka, Proceedings of the National Academy of Sciences
  28. Gurdon and Yamanaka Win Nobel Prize for Stem Cell Research, New York Times
  29. 29.0 29.1 Skin cells reprogrammed into brain cells, Science Daily
  30. 30.0 30.1 Reprogamming Cells Could Eliminate Dangers of Side Effects in Medicine, US News & World Report
  31. The Nobel Prize in Physiology or Medicine 2012 , Nobelprize.org
  32. Scientists unveil genetic microbe map, KGO-TV

External links