Gladstone Institutes

History

Research Programs

• Early heart development and congenital birth defects. Determining the biological steps in the embryonic development of the human heart to identify genes, RNAs or proteins that can be targeted to treat congenital heart disease.
• Regenerative medicine to repair damaged hearts. Regenerating hearts by converting scar tissue into beating cardiac muscle. Creating heart cells from skin samples of patients with many cardiovascular diseases, such as calcification of the aortic valve, to test the safety and efficacy of new or existing drugs to treat or prevent the conditions.
• Lipid metabolism. Defining the enzymes involved in triglyceride biosynthesis and the cell biology underlying lipid storage in cells, as a way to understand obesity-related illnesses—such as heart disease and diabetes—at the cellular level.
• Human evolution. Exploring the most rapidly evolving areas of the human genome to improve understanding of human disease and evolution.

• “Treatment as prevention” strategies to blunt the rate of new HIV infections. Led by Gladstone scientists, the global iPrEx study showed how a daily pill could prevent HIV infection in people likely to be exposed; this study is currently in Phase-III clinical trials.
• HIV integration. Investigating the mechanisms by which HIV integrates and replicates within human hosts—while evading the host immune system.
• HIV Pathogenesis. Investigating the mechanisms by which HIV infects and kills lymphoid CD4 T-cells, the fundamental cause of AIDS, and the role of inflammation as a driver of HIV pathogenesis.
• HIV latency. Investigating HIV latency as a member of the Martin Delaney Collaboratory—a consortium including academia, government and private industry. Latency occurs when HIV goes dormant and “hides” within cells, waiting for an opportunity to reemerge when antiretroviral medications are stopped.
• HIV and aging. Determining whether chronic, low-level inflammation associated with the disease—or the antiretroviral drugs used to treat HIV infection—are the major factors driving “accelerated aging” associated with HIV/AIDS.
• Hepatitis C. Pathogenesis and targets for therapeutic intervention. Looking for new biological targets for drugs that will attack the hepatitis C virus.
• Immunology of viral infection. Exploring the genomic regulation of viruses associated with cancer. Investigating why newborns and infants mount less effective immune responses to viruses than adults do.

• Alzheimer's disease and network disruption. Studying how damage to neurons affects their ability to communicate through chemical and electrical signals, which manifests as sub-clinical epileptic-like seizures. Discovered a link between this process and many of the deficits linked to Alzheimer's disease.
• Alzheimer's disease and apolipoprotein E . Uncovered the molecular pathways that link apoE and Alzheimer's disease, and identifying new drugs that counteract detrimental effects of apoE4—the most important genetic risk factor for Alzheimer's.
• Alzheimer's disease and tau. Understanding how lowering brain levels of the protein tau improves memory and other cognitive functions in mice genetically engineered to mimic Alzheimer's disease. Exploring therapeutic strategies to block tau's disease-promoting activities.
• TDP-43. Studying TDP-43, another protein that may contribute to diverse neurodegenerative disorders.
• Protein aggregates and their role in neurodegenerative disease. Helping to uncover the mystery behind protein aggregations—observed in Huntington's disease, Parkinson's disease, and Alzheimer's disease —discovering that rather than being the culprit of neuronal death, these aggregates are part of a defense mechanism that safely sequesters toxin proteins in the brain, preventing them from wreaking further havoc.
• Neural circuits involved in Parkinson’s disease. Investigating the network of brain cells that controls movement in order to figure out how its dysfunction leads to the symptoms of Parkinson’s disease.
• Mitochondria and synaptic dysfunction. Studying mitochondria, the energy-producing subunits of cells, as their impairment appears to play an important role in multiple neurodegenerative conditions, including Alzheimer's, Parkinson’s and ALS.
• Autophagy. Researching how autophagy—a process by which cells eliminate abnormal proteins—can help prevent the destruction of brain cells. Discovering how the p75 neurotrophin receptor—a protein long known for its role in the development of brain cells—plays unexpected roles in both Alzheimer's and Type 2 diabetes.
• Inflammation and neurodegenerative disease. Studying abnormal inflammatory responses by immune cells in the central nervous system—which may contribute to the progression of multiple sclerosis, neurodegenerative disorders and many other neurological conditions.
• Frontotemporal dementia . Showed a protein called progranulin prevents a type of brain cells from becoming "hyperactive." If not enough progranulin is available the hyperactivity can become toxic and result in extensive inflammation that kills brain cells and can lead to the development of FTD. Also showed that too much of another protein called TDP-43 plays a role in FTD disease progression. Importantly, Gladstone scientists have identified a means to suppress the toxic effects of TDP-43 for FTD and for another neurodegenerative disease: ALS.

• Reprogramming cardiac connective tissue located in the heart directly into beating cardiac muscle cells.
• Discovering new ways to use chemical compounds to convert cells from one type into another.
• Direct reprogramming of cells into neurons and neural precursor cells.
• Using iPS cells to create human models to research solutions for Huntington's disease and Alzheimer's disease.
• Studying whether the retrotransposons residing in our DNA become more active when a skin cell is reprogrammed into an iPS cell.
• Using iPS technology to create a new model for testing a vaccine for HIV/AIDS.

Researchers

• 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.
• 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 that, like embryonic stem cells, can then develop into other cell types. Since he first announced this research in 2006 and in 2007, 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.
• 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.
• 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.
• 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.
• 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.
• Warner C. Greene—Provided insight into the precise mechanisms of how HIV attacks the human immune system, and how small fibrils found in semen enhance the ability of HIV to infect cells—paving the way for the development of new ways to prevent the spread of the virus. Identifying pyroptosis as the predominant mechanism that causes the two signature pathogenic events in HIV infection––CD4 T-cell depletion and chronic inflammation. Identifying pyroptosis may provides novel therapeutic opportunities targeting caspase-1, which controls the pyroptotic cell death pathway. Specifically, these findings could open the door to an entirely new class of “anti-AIDS” therapies that act by targeting the host rather than the virus.
• 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. In 2018 published an article in Nature Medicine about Apolipoprotein E gene expression - pluripotent stem cell cultures from patients with Alzheimer's disease with the APOE-ε4 polymorphism were treated with a “structure corrector” that made the protein expressed similar to that of the APOE-ε3 allele.
• Robert “Bob” W. Mahley — Established the importance of the protein apoE while working at the National Institutes of Health, later making significant contributions to science’s understanding of the critical role that apoE plays in heart disease and Alzheimer's disease.
• 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.
• 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.
• R. Sanders 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.
• Jennifer Doudna — CRISPR gene editing pioneer, working to adapt the technology towards applications in biotechnology and medicine, including developing a rapid diagnostic test for COVID-19
• Melanie Ott — Ott's research program centers on understanding how viruses hijack their host's cells in order to better identify drug targets to prevent the spread of infection. She's worked on re-purposing drugs currently used to treat cancer by targeting a cell's epigenetic machinery towards more effectively treating HIV infections. She is now directing her research efforts towards addressing the COVID-19 pandemic.