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Tag: Sanford Burnham Prebys

  • Study reveals Zika’s shape-shifting machinery—and a possible vulnerability

    Study reveals Zika’s shape-shifting machinery—and a possible vulnerability

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    Newswise — Viruses have limited genetic material—and few proteins—so all the pieces must work extra hard. Zika is a great example; the virus only produces 10 proteins. Now, in a study published in the journal PLOS Pathogens, researchers at Sanford Burnham Prebys have shown how the virus does so much with so little and may have identified a therapeutic vulnerability.

    In the study, the research team showed that Zika’s enzyme—NS2B-NS3—is a multipurpose tool with two essential functions: breaking up proteins (a protease) and dividing its own double-stranded RNA into single strands (a helicase).

    “We found that Zika’s enzyme complex changes function based on how it’s shaped,” says Alexey Terskikh, Ph.D., associate professor at Sanford Burnham Prebys and senior author of the paper. “When in the closed conformation, it acts as a classic protease. But then it cycles between open and super-open conformations, which allows it to grab and then release a single strand of RNA—and these functions are essential for viral replication.”

    Zika is an RNA virus that’s part of a family of deadly pathogens called flaviviruses, which include West Nile, dengue fever, yellow fever, Japanese encephalitis and others. The virus is transmitted by mosquitoes and infects uterine and placental cells (among other cell types), making it particularly dangerous for pregnant women. Once inside host cells, the virus re-engineers them to produce more Zika.

    Understanding Zika on the molecular level could have an enormous payoff: a therapeutic target. It would be difficult to create safe drugs that target the domains of the enzyme needed for protease or helicase functions, as human cells have many similar molecules. However, a drug that blocks Zika’s conformational changes could be effective. If the complex can’t shape-shift, it can’t perform its critical functions, and no new Zika particles would be produced.

    An efficient machineResearchers have long known that Zika’s essential enzyme was composed of two units: NS2B-NS3pro and NS3hel. NS2B-NS3pro carries out protease functions, cutting long polypeptides into Zika proteins. However, NS2B-NS3pro’s abilities to bind single-stranded RNA and help separate the double-stranded RNA during viral replication were only recently discovered.

    In this study, the researchers leaned on recent crystal structures and used protein biochemistry, fluorescence polarization and computer modeling to dissect NS2B-NS3pro’s life cycle. NS3pro is connected to NS3hel (the helicase) by a short amino acid linker and becomes active when the complex is in its closed conformation, like a closed accordion. The RNA binding happens when the complex is open, whereas the complex must transition through the super-open conformation to release RNA.

    These conformational changes are driven by the dynamics of NS3hel activity, which extends the linker and eventually “yanks” the NS3pro to release RNA. NS3pro is anchored to the inside of the host cell’s endoplasmic reticulum (ER)—a key organelle that helps shepherd cellular proteins to their appropriate destinations—via NS2B and, while in the closed conformation, cuts up the Zika polypeptide, helping generate all viral proteins.

    On the other side of the linker, NS3hel separates Zika’s double-stranded RNA and conveniently hands a strand over to NS3pro, which has positively charged “forks” to grab on to the negatively charged RNA.

    “There’s a very nice groove of positive charges,” says Terskikh. “So, RNA just naturally follows that groove. Then the complex shifts to the closed conformation and releases the RNA.”

    As NS3hel reaches forward to grab the double-stranded RNA, it pulls the complex with it; however, since the NS3pro is anchored in the ER membrane, and the linker can only extend so far, the complex snaps into the super-open conformation and releases RNA. The complex then relaxes back to the open conformation, ready for a new cycle.

    Meanwhile, when NS3pro detects a viral polypeptide to cut, it forces the complex into the closed conformation, becoming a protease. The authors call this process “reverse inchworm,” because grabbing and releasing the single-stranded RNA resembles inchworm movements, but backward with the jaws (the protease) trailing behind.

    In addition to providing a possible therapeutic target for Zika, this detailed understanding could be applied to other flaviviruses, which share similar molecular machinery.

    “Versions of the NS2B-NS3pro complex are found throughout the flaviviruses,” says Terskikh. “It could potentially constitute a whole new class of drug targets for multiple viruses.”

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    Additional authors include Sergey A. Shiryaev, Piotr Cieplak, Anton Cheltsov and Robert C. Liddington.

    This study was supported by grants from the National Institutes of Health (5R21AI134581 and R01 NS105969).

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  • Copycat nutrient leaves pancreatic tumors starving

    Copycat nutrient leaves pancreatic tumors starving

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    Newswise — LA JOLLA, CALIF. – 2023 – A study led by scientists at Sanford Burnham Prebys suggests an entirely new approach to treat pancreatic cancer. The research shows that feeding tumors a copycat of an important nutrient starves them of the fuel they need to survive and grow. The method, described in the journal Nature Cancer, has been used in early clinical trials for lung cancer. However, the unique properties of pancreatic cancer may make the strategy an even stronger candidate in the pancreas.

    “Pancreatic cancer relies on the nutrient glutamine much more than other cancers, so therapies that can interfere with tumors’ ability to access glutamine could be highly effective,” says senior author Cosimo Commisso, Ph.D., director and associate professor of the Cancer Metabolism and Microenvironment Program at Sanford Burnham Prebys.

    Pancreatic cancer is relatively rare, accounting for only 3% of all cancers. However, it has one of the lowest survival rates among cancers: most people only live three to six months after being diagnosed with this disease.

    “Over the course of the past decade, there has been a notable improvement in survival rates for pancreatic cancer, but they still hover around just 10%,” says Commisso. “There is a dire need for new treatments for these cancers.”

    One of the challenges of treating pancreatic cancer has to do with the physical properties of the tumors themselves.

    “Pancreatic tumors tend to be packed in dense connective tissue that keeps them encapsulated from the rest of the body and cuts off their supply of oxygen,” says Commisso. “As a consequence, these cancers develop unique metabolic properties compared to other tumors, and this is something we may be able to exploit with new treatments.”

    One of the metabolic quirks of pancreatic cancer is that it relies heavily on glutamine to produce energy for growth and survival. In the past, scientists have tried to block access to glutamine to slow the growth of pancreatic tumors, but this is easier said than done.

    The new method relies on a molecule called DON that has structural similarities to glutamine but can’t actually be used as a nutrient source. By studying mice, the research team found that DON significantly slowed pancreatic tumor growth and stopped the tumors from spreading.

    Although DON was able to stop pancreatic tumors from using glutamine, pancreatic cancer cells can use other nutrients to grow in glutamine’s absence. To combat this effect, the researchers combined DON with an existing cancer treatment that blocks the metabolism of asparagine, another important nutrient. The combined treatment had a synergistic effect, helping prevent the spread of pancreatic tumors to other distant organs, such as the liver and lungs.

    “With DON, the cancer cells can’t use glutamine, but they can start to depend on other nutrients as a backup, including asparagine,” says Commisso. “We thought that if we could stop them from using glutamine and asparagine, the tumors would run out of options.”

    Although this is the first time this combination of treatments has been proposed for any cancer, the approach of using DON on its own has already advanced to early clinical trials in lung cancer.

    “This is particularly exciting, because exploring it further for pancreatic cancer patients could be relatively simple, since the study designs exist for other solid tumors,” adds Commisso. “This could be a game changer for pancreatic cancer, and a lot of the preclinical work needed to rationalize it is already happening.”

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    Additional authors on the study include Maria Victoria Recouvreux, Shea Grenier, Yijuan Zhang, Guillem Lambies, Cheska Marie Galapate, Swetha Maganti, Karen Duong-Polk, Deepika Bhullar, David A. Scott and Razia Naeem, Sanford Burnham Prebys; Edgar Esparza, Andrew M. Lowy and Hervé Tiriac, University of California San Diego.

    This study was supported by an American Cancer Society Discovery Boost Grant (DBG-22-172-01-TBE) and grants from the NIH (R01CA254806, R01CA207189).

    The study’s DOI is 10.1038/s43018-023-00649-1.

    About Sanford Burnham Prebys

    Sanford Burnham Prebys is an independent biomedical research institute dedicated to understanding human biology and disease and advancing scientific discoveries to profoundly impact human health. For more than 45 years, our research has produced breakthroughs in cancer, neuroscience, immunology and children’s diseases, and is anchored by our NCI-designated Cancer Center and advanced drug discovery capabilities. For more information, visit us at SBPdiscovery.org or on Facebook facebook.com/SBPdiscovery and on Twitter @SBPdiscovery.

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  • This sugar kills honeybees—it could also help fight cancer

    This sugar kills honeybees—it could also help fight cancer

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    Newswise — LA JOLLA, CALIF. – July 18, 2023 – Research from Sanford Burnham Prebys and the Osaka International Cancer Institute has shed new light on the anti-cancer properties of mannose, a sugar that is crucial to many physiological processes in humans and is also known to inhibit the growth of cancer cells. The findings, published in the journal eLife, suggest that mannose could be a helpful secondary treatment for cancer.

    “This sugar could give cancer an extra punch alongside other treatments,” says study co-author Hudson Freeze, Ph.D., director of the Human Genetics Program at Sanford Burnham Prebys. “And because mannose is found throughout the body naturally, it could improve cancer treatment without any undesirable side effects.”

    Mannose is a sugar that the body adds to proteins to stabilize their structure and help them interact with other molecules. This process, called glycosylation, is essential for life; and malfunctions in glycosylation are associated with rare, but often life-threatening, human diseases.

    “Until now, the most promising therapeutic use for mannose was to treat congenital disorders of glycosylation, diseases that can cause a wide range of severe symptoms throughout the body,” says Freeze. “But we believe that there may be ways to leverage mannose against cancer and other diseases as well.”

    Mannose has already been shown to inhibit the growth of several types of cancer in the lab, but scientists don’t fully understand why this happens. To learn more, the research team turned their attention to an unusual property of mannose observed in an unlikely subject: honeybees. 

    “It’s been known for more than a century that mannose is lethal to honeybees because they can’t process it like humans do—it’s known as ‘honeybee syndrome,’” says Freeze. “We wanted to see if there is any relationship between honeybee syndrome and the anti-cancer properties of mannose, which could lead to an entirely new approach to combat cancer.” 

    Using genetically engineered human cancer cells from fibrosarcoma—a rare cancer that affects connective tissue—the research team re-created honeybee syndrome and discovered that without the enzyme needed to metabolize mannose, cells replicate slowly and are significantly more vulnerable to chemotherapy. 

    “We found that triggering honeybee syndrome in these cancer cells made them unable to synthesize the building blocks of DNA and replicate normally,” says Freeze. “This helps explain the anti-cancer effects of mannose that have we’ve observed in the lab.” 

    While leveraging honeybee syndrome could be a promising supplemental cancer treatment, the researchers caution that because the effect is dependent on vital metabolic processes, more research is needed to determine which types of cancer would be most vulnerable to mannose.

    “If we can find cancers that have a low activity of the enzyme that processes mannose, treating them with mannose could give just enough of a nudge to make chemotherapy more effective,” says Freeze. “Many people assume that you always discover treatments in response to the disease, but sometimes you find biology that could be useful for treatment and then have to find the disease to match it.”

    In the meantime, the study speaks to the broader potential of glycosylating sugars for cancer treatment, which is still an emerging area of research. 

    “The glycobiology of sugar metabolism within cancer cells is still an unexplored frontier, and it could be an untapped treasure trove of potential treatments just waiting to be discovered,” adds Freeze. 

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    Additional authors on the study include Yoichiro Harada, Yu Mizote, Toru Hiratsuka, Yusuke Imagawa, Kento Maeda, Yuki Ohkawa, Shigeki Higashiyama, Hideaki Tahara and Naoyuki Taniguchi, Osaka International Cancer Institute; Takehiro Suzuki and Naoshi Dohmae, RIKEN Center for Sustainable Resource Science; Akiyoshi Hirayama, Satsuki Ikeda and Junko Murai, Keio University; Mikako Nishida and Heiichiro Udono, Okayama University Graduate School of Medicine, Dentistry and Pharmaceutical Sciences; and Ayaka Ueda and Eiji Miyoshi, Osaka University. 

    The study was supported by the Takeda Science Foundation, JSPS KAKENHI (JP23K06645), the Rocket Fund, and the National Institutes of Health (R01DK99551).

    The study’s DOI is 10.7554/eLife.83870.

    About Sanford Burnham Prebys

    Sanford Burnham Prebys is an independent biomedical research institute dedicated to understanding human biology and disease and advancing scientific discoveries to profoundly impact human health. For more than 45 years, our research has produced breakthroughs in cancer, neuroscience, immunology and children’s diseases, and is anchored by our NCI-designated Cancer Center and advanced drug discovery capabilities. For more information, visit us at SBPdiscovery.org or on Facebook facebook.com/SBPdiscovery and on Twitter @SBPdiscovery.

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  • New algorithm can predict diabetic kidney disease

    New algorithm can predict diabetic kidney disease

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    Newswise — LA JOLLA, CALIF. – May 15, 2023 – Researchers from Sanford Burnham Prebys and the Chinese University of Hong Kong have developed a computational approach to predict whether a person with type 2 diabetes will develop kidney disease, a frequent and dangerous complication of diabetes. Their results, published in Nature Communications, could help doctors prevent or better manage kidney disease in people with type 2 diabetes.

    “This study provides a glimpse into the powerful future of predictive diagnostics,” says co-senior author Kevin Yip, Ph.D., a professor and director of Bioinformatics at Sanford Burnham Prebys. “Our team has demonstrated that by combining clinical data with cutting-edge technology, it’s possible to develop computational models to help clinicians optimize the treatment of type 2 diabetes to prevent kidney disease.”

    Diabetes is the leading cause of kidney failure worldwide. In the United States, 44% of cases of end-stage kidney disease and dialysis are due to diabetes. In Asia, this number is 50%.

    “There has been significant progress developing treatments for kidney disease in people with diabetes,” says co-senior author Ronald Ma, MB BChir, FRCP, a professor in the Department of Medicine and Therapeutics at the Chinese University of Hong Kong. “However, it can be difficult to assess an individual patient’s risk for developing kidney disease based on clinical factors alone, so determining who is at greatest risk of developing diabetic kidney disease is an important clinical need.”

    The new algorithm depends on measurements of a process called DNA methylation, which occurs when subtle changes accumulate in our DNA. DNA methylation can encode important information about which genes are being turned on and off, and it can be easily measured through blood tests.

    “Our computational model can use methylation markers from a blood sample to predict both current kidney function and how the kidneys will function years in the future, which means it could be easily implemented alongside current methods for evaluating a patient’s risk for kidney disease,” says Yip.

    The researchers developed their model using detailed data from more than 1,200 patients with type 2 diabetes in the Hong Kong Diabetes Register. They also tested their model on a separate group of 326 Native Americans with type 2 diabetes, which helped ensure that their approach could predict kidney disease in different populations.

    “This study highlights the unique strength of the Hong Kong Diabetes Register and its huge potential to fuel further discoveries to improve our understanding of diabetes and its complications,” says study co-author Juliana Chan, M.D., FRCP, a professor in the Department of Medicine and Therapeutics at the Chinese University of Hong Kong, who established the Hong Kong Diabetes Register more than two decades ago.

    “The Hong Kong Diabetes Register is a scientific treasure,” adds first author Kelly Yichen Li, Ph.D., a postdoctoral scientist at Sanford Burnham Prebys. “They follow up with patients for many years, which gives us a full picture of how human health can change over decades in people with diabetes.”

    The researchers are currently working to further refine their model. They are also expanding the application of their approach to look at other questions about human health and disease—such as determining why some people with cancer don’t respond well to certain treatments.

    “The science is still evolving, but we are working on incorporating additional information into our model to further empower precision medicine in diabetes,” adds Ma.

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    Additional authors on the study include Claudia Ha Ting Tam, Cadmon King Poo Lim, Wing Yee So, Chuiguo Huang, Guozhi Jiang, Mai Shi, Hueng Man Lee, Hui-yao Lan and Cheuk-Chun Szeto, Chinese University of Hong Kong; Hongbo Liu, Katalin Susztak, University of Pennsylvania; Samantha Day, Robert L. Hanson and Robert G. Nelson, National Institute of Diabetes and Digestive and Kidney Diseases.

    The study was supported by grants from The Hong Kong Research Grants Council Theme-based Research Scheme (T12-402/13N) and Research Impact Fund (R4012-18), with additional support from the Research Grants Council (C4015-20E, C4045-18W, C4057-18E, C7044-19G, 14107420 and 14203119), National Institutes of Health (P30 CA030199-41, U54 AG079758-01, R21 AG075483-01S1, R01 DK087635, DK076077 and DK105821) and support from the Croucher Foundation and the Chinese University of Hong Kong.

    The study’s DOI is 10.1038/s41467-023-37837-7

    About Sanford Burnham Prebys

    Sanford Burnham Prebys is an independent biomedical research institute dedicated to understanding human biology and disease and advancing scientific discoveries to profoundly impact human health. For more than 45 years, our research has produced breakthroughs in cancer, neuroscience, immunology and children’s diseases, and is anchored by our NCI-designated Cancer Center and advanced drug discovery capabilities. For more information, visit us at SBPdiscovery.org or on Facebook facebook.com/SBPdiscovery and on Twitter @SBPdiscovery.

    About the Faculty of Medicine, The Chinese University of Hong Kong (CU Medicine)

    CU Medicine was set up to meet the needs of society by providing graduates with the professional development and knowledge that equips them to be caring and competent medical practitioners. As a young medical school established in 1981, the Faculty ranks top 3 in Asia and 32nd globally in the QS World University Rankings by Subject 2023.

    We have a team of over 1,200 full-time teaching and research staff from 19 departments/schools covering the entire range of research and clinical disciplines. We encourage collaborative working between scientists and clinicians across disciplines and specialties, and remain at the forefront of the translational medicine revolution. Our Faculty members excel in tackling challenging health problems, making a memorable impact on patients’ lives and the wider society.

    CU Medicine has won an internationally renowned research reputation for its encouraging environment for the effective pursuit of world-class research as well as remarkable contributions from team members.

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  • Reviving exhausted T cells to tackle immunotherapy-resistant cancers

    Reviving exhausted T cells to tackle immunotherapy-resistant cancers

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    Newswise — LA JOLLA, CALIF. – May 03, 2023 – When the cells of our immune system are under constant stress due to cancer or other chronic diseases, the T cells of the immune system shut down in a process called T cell exhaustion. Without active T cells, which kill tumor cells, it’s impossible for our bodies to fight back against cancer. One of the biggest goals of immunotherapy is to reverse T cell exhaustion to boost the immune system’s ability to destroy cancerous cells.

    Researchers at Sanford Burnham Prebys studying melanoma have found a new way to make this happen. Their approach, described in Cell Reports, can reduce T cell exhaustion even in tumors that are resistant to clinically approved immunotherapies. It can also help T cells from becoming exhausted.

    “Slowing or reversing T cell exhaustion is a huge focus in cancer research, and many researchers are working on different ways to accomplish this,” says first author Jennifer Hope, Ph.D., who completed this research as a postdoctoral researcher at Sanford Burnham Prebys and is now an assistant professor at Drexel University. “This new approach could be a viable treatment on its own, but it also has tremendous potential to work synergistically with existing therapies.”

    Although there are established immunotherapies that target T cell exhaustion, the new approach is unique in that it targets several different aspects of the process at once. This means that it could help people overcome resistance to various anti-cancer immunotherapies that are currently available.

    “One of the foundational ideas of modern cancer treatment is not relying on a single therapy, since this can cause the cancer to become resistant to that treatment,” says senior author Linda Bradley, Ph.D., a professor in the Cancer Metabolism and Microenvironment Program at Sanford Burnham Prebys. “The more tools at our disposal to slow down or reverse T cell exhaustion in different ways, the better chance we have of improving precision medicine and helping more people with cancer benefit from immunotherapy.”

    Their approach hinges on a protein called PSGL-1, which is found in most blood cells. By studying mice with a genetic deficiency in PSGL-1, the researchers determined that this protein helps facilitate T cell exhaustion, a major roadblock to effective anti-cancer immunity.

    The researchers then used an antibody to block the activity of PGSL-1 in mice with immunotherapy-resistant melanoma. They found that targeting PSGL-1 slowed the process of T cell exhaustion and helped exhausted T cells switch back into functioning T cells. These two effects significantly reduced tumor growth in the mice.

    “One of the things that makes this approach unique compared to existing immunotherapies is that it directly alters the way T cells become exhausted and helps them regain their function,” says Hope. “I think this is going to be crucial in terms of its translational potential.”

    The researchers were also able to replicate this effect in mice with mesothelioma, suggesting that the approach could be applicable to a wide range of cancers. Although the treatment they used in this study is not yet suited for clinical use in humans, the overall approach of using antibodies or recombinant proteins for immunotherapy is well established. This means that translating these results for people with cancer may just be a matter of time and testing.

    “Once we’ve done all the necessary science, this could be really valuable, or even lifesaving, for a lot of people with cancers that are resistant to current treatments,” says Bradley. “We still have a long way to go, but I’m optimistic that we’re onto something game-changing here.”

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    Additional authors on the study include Dennis C. Otero, Eun-Ah Bae, Christopher J. Stairiker, Ashley B. Palete, Hannah A. Faso, Michelle Lin, Monique L., Henriquez, Sreeja Roy, Xue Lei, Eric S. Wang, Savio Chow, Roberto Tinoco, Kevin Yip, Alexandre Rosa Campos, Jun Yin, Peter D. Adams and Linda M. Bradley, Sanford Burnham Prebys; Anjana Rao and Hyungseok Seo, La Jolla Institute for Immunology; and Gregory A. Daniels, Moores Cancer Center at UC San Diego Health.

    The study was supported by grants from the American Cancer Society (PF-20-113-01-LIB), the National Institutes of Health (T32 AI125209, R01 AI106895, R21 CA249353, R21 CA216678, R03 CA252144, R01 AI040127, R01 AI109842, P30 CA030199), the Melanoma Research Alliance (MRA 696326), the Department of Defense (W81XWH-20-1-0324), the American Association of Immunologists, the San Diego Cancer Centers Council (C3 2018), the Association of Immunologists Careers in Immunology Fellowship Program, and was supported in part by the following Sanford Burnham Prebys Core facilities: Flow Cytometry, Vivarium, Histology, Bioinformatics, Proteomics, and Cancer Metabolism.

    The study’s DOI is 10.1016/j.celrep.2023.112436

    About Sanford Burnham Prebys

    Sanford Burnham Prebys is an independent biomedical research institute dedicated to understanding human biology and disease and advancing scientific discoveries to profoundly impact human health. For more than 45 years, our research has produced breakthroughs in cancer, neuroscience, immunology and children’s diseases, and is anchored by our NCI-designated Cancer Center and advanced drug discovery capabilities. For more information, visit us at SBPdiscovery.org or on Facebook facebook.com/SBPdiscovery and on Twitter @SBPdiscovery.

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  • Sanford Burnham Prebys researchers team up to discover potential pancreatic cancer drugs

    Sanford Burnham Prebys researchers team up to discover potential pancreatic cancer drugs

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    Newswise — LA JOLLA, CALIF. – Jan 05, 2023 – Cosimo Commisso, Ph.D., and Susanne Heynen-Genel, Ph.D., have received a grant from the National Cancer Institute (NCI) to advance a new treatment approach for pancreatic cancer. The four-year, $X project will identify potential drugs that can manipulate the pH of cells to stop pancreatic tumors from growing. The promising approach would selectively kill pancreatic cancer cells without affecting surrounding healthy cells.

    “Pancreatic cancer is a growing global health crisis, and there is an urgent need for better ways to treat it,” says Commisso, an associate professor at Sanford Burnham Prebys. “This project will help us find molecules that are the starting points to create new medicines.”

    Pancreatic cancer accounts for just 3% of cancer cases in the United States, but it is so difficult to treat that it is projected to become the second-leading cause of cancer-related death by 2030. According to the NCI, about 49,830 people died from pancreatic cancer in the United States in 2022.

    “Pancreatic cancer tends to be diagnosed late, because it’s an organ lying deep in the body and can grow undetected for years,” says Commisso. “Since I started working in this field more than a decade ago, we’ve managed to double the survival rates for people with pancreatic cancer. But that’s not good enough—the five-year survival rate after diagnosis is only around 10%.”

    Commisso and his team discovered that pancreatic cancer cells have a unique way of regulating their pH—a measure of acidity. Cells need to maintain a pH within a certain range to survive and grow. Pancreatic cancer cells control their pH by packaging up excess acid and storing it separately from the rest of the cell’s fluids. This process doesn’t occur in healthy cells.

    “One really promising aspect of this approach is that once we find the right drug, we’ll be able to kill the cancer cells without causing any damage to the rest of the body,” says Commisso.

    “Metabolic approaches like this are the future of targeted cancer therapy.”
    Transforming Commisso’s discoveries into a real medicine will require the drug discovery capabilities of Heynen-Genel and her team at the Conrad Prebys Center for Chemical Genomics

    “This is such an important grant because it supports the first steps toward translating this novel discovery into a new treatment that could give hope to so many people with pancreatic cancer,” says Heynen-Genel. “This grant helps us lay the groundwork to figure out how this research could be applied in the clinic.”

    The researchers will screen hundreds of thousands of molecules and identify a select few “hits” that have desirable biological effects and chemical properties. Then they will conduct other studies on these hits to see which have the most potential to fight pancreatic cancer with minimal side effects. By the end of the grant, the team will have several drug candidates that can be developed further toward anticancer therapies. 

    “We could find the next major breakthrough in pancreatic cancer treatment, but we have to put in the legwork now to find out,” says Heynen-Genel. “That’s what’s exciting about drug discovery. It feels like it has infinite potential.”

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