AML Archives - Sanford Burnham Prebys
Institute News

New genome mapping tool may uncover secrets for treating blood cancers

AuthorGreg Calhoun
Date

February 1, 2024

The outlook for patients with acute myeloid leukemia (AML), a deadly set of blood cancers that is difficult to treat, has remained dire for decades, especially among patients who are not eligible for bone marrow transplantation.

More than 30% of treated patients will never achieve complete remission using current chemotherapies and, even when chemotherapy treatments work, most patients relapse within five years without a transplant.

Kristiina Vuori, MD, PhDWhile prior research has begun to unravel the genetic underpinnings of the disease, more inquiry is needed to understand the genetic variation within the roughly 15 AML subtypes and how that variation might affect treatment strategies.

“In addition to the one to eight average genetic mutations in AML patients found in traditional sequencing studies, experiments employing high-resolution optical genomic mapping have found approximately 40 to 80 rare genomic structural variants per patient,” says Kristiina Vuori, MD, PhD, Pauline and Stanley Foster Distinguished Chair and professor in the Sanford Burnham Prebys Cancer Center’s Cancer Molecular Therapeutics Program. “We wanted to take these structural variant findings in AML to the next level by connecting them with patients’ sensitivity or resistance to current cancer treatments.”

In a paper published January 18, 2024, in Cancers, a multidisciplinary team of biologists, bioinformaticians and clinicians from Sanford Burnham Prebys, Bionano Genomics Inc. and Scripps MD Anderson were the first to associate genomic structural variants (SVs) in AML patients with drug sensitivities.

Darren (Ben) Finally, PhD“SVs are changes to the genome in which sections of 50 or more base pairs in a strand of DNA have been errantly deleted, duplicated, inverted or translocated,” explains Darren (Ben) Finlay, PhD, first author on the manuscript and research associate professor in the Sanford Burnham Prebys Cancer Center.

“Such changes amount to different combinations of DNA gains, losses or rearrangements. When cells use these altered instructions in the DNA to make proteins or carry out other functions, it is like a chef trying to cook with a recipe that is missing steps, has them in the wrong order or includes more or less of the key ingredients.”

Scientists have become more able to find SVs as next-generation genomic analysis technologies and techniques have improved. Research has shown that SVs contribute to the development and progression of cancer, including blood cancers. Of particular concern among SVs are DNA changes that join two otherwise distant genes. This event, called gene fusion, is known to drive certain pediatric and blood cancers.

Finlay, Vuori and colleagues analyzed SVs in samples from 23 AML patients and found their genomes featured 16-45 extremely rare SVs within genes but not seen in healthy volunteers’ samples. The scientists detailed the patients’ SVs using a technique called optical genome mapping. This tool tags DNA in specific locations to create recognizable sequences, unwinds and straightens the genomic DNA for linear scanning, and converts the imaged sequences into digital representations of DNA molecules. Because it directly images DNA rather than relying on algorithmic analyses, optical genome mapping is better than next-generation sequencing at finding SVs throughout the entire genome, especially large SVs, the researchers said.

To begin building the connection between SVs and drug sensitivity, the scientists tested samples from each patient with 120 FDA-approved drugs, and experimental treatments currently in phase III clinical trials. This allowed the researchers to map out how strongly each patient’s sample reacted with each drug.

Next, the investigators used statistical analysis to compare the SVs within the optical genome mapping results with the findings from the drug sensitivity tests. The team found 61 statistically significant interactions between SVs and existing cancer therapies. In one interaction, the group demonstrated that a commonly used AML drug, Idarubicin, and two similar compounds (Daunorubicin and Epirubicin) were more effective in leukemia samples with a specific insertion in a gene that carries the instructions for a signaling enzyme that helps nerves communicate with muscles. These and other examples lend support to the scientists’ hypothesis that optical genome mapping could be used to develop personalized treatment plans that account for patients’ SVs.

“In this pilot study, our hope was to identify structural variants that could be used as new biomarkers for current AML drugs as well as to identify other drugs that could be repurposed to treat leukemia patients,” says Finlay.

“Ensuring patients receive the most effective drugs on the market through personalized treatment and identifying new potential therapies for AML are critically important,” adds Vuori, senior author on the study. “Especially for patients who do not achieve remission with current standard chemotherapies or who are ineligible for bone marrow transplants or clinical trials.”
 

Cancers 2024, 16(2), 418; https://doi.org/10.3390/cancers16020418

Institute News

How community collaboration shapes leukemia research at Sanford Burnham Prebys

AuthorMiles Martin
Date

October 4, 2022

Since 2020, Todd and Rena Johnson, co-founders of the Luke Tatsu Johnson Foundation (LTJF), have helped fund the research of Associate Professor Ani Deshpande, PhD

But it all started with their son Luke. He had a very rare subtype of acute myeloid leukemia, one of the most difficult-to-treat cancers, and, sadly, he passed away from the disease in 2016. This inspired the Johnsons to become involved with fundraising and advocacy for cancer research.

Luke Tatsu Johnson
Luke Tatsu Johnson

“Our foundation started with a fundraising golf tournament to honor Luke, and that was about taking something so horrific and so horrible and finding a way to turn it into something positive,” says Rena. “If you can take that tragedy and put a positive spin on it, then everything around Luke and his name and his memory becomes positive.”
 

How “the stars and planets aligned” to bring the Johnsons to the Institute

In a remarkable coincidence, the Johnsons discovered on their first visit to the Institute that Deshpande’s research focuses on AF10 fusion AML, an extremely rare subtype of the disease that accounts for about 5 percent of cases. It’s also the subtype of AML that Luke had.

“It was a goosebumps-raising moment,” says Todd. “Once we visited Ani and saw his lab, we realized there was a lot more in common with our story and his research than we had realized before.”

“The stars and planets aligned and brought us to Ani,” adds Rena. 

As well as helping fund Deshpande’s research through LTJF and their partnership with the Rally! Foundation, the Johnsons are also on the Community Advisory Board (CAB) for the Institute’s Cancer Center, which advocates for cancer research by engaging the community. 

“The CAB does such a wonderful job of connecting the community with the scientists, and we’re so excited to be involved in that,” says Todd. “That’s fundamentally what we do as a foundation—we support the folks doing this work so that children and families down the road can have a different outcome from Luke’s.”
 

AML research “needs more support and needs more funding”

The Johnsons’ support helped the AML research team discover a new potential treatment for AML, which is currently in preclinical studies, after which they hope it will advance to clinical trials. The research team maintains that it would have been impossible to secure the NIH grants necessary to do these studies without the jump start given by the LTJF and the Rally! Foundation.

“We couldn’t do what we do without the Johnsons’ support,” says Deshpande. “We are so grateful to have them in our corner, and we’re confident that our work will help improve outcomes for kids like Luke down the line.”

Despite this progress, more research into AML and other leukemias is still needed. Leukemia is the most common cancer in children and teens. About 4,000 children are diagnosed with leukemia each year, and AML accounts for about a third of these cases.
 

Studying AML from all angles

To tackle this pressing problem, the Institute has established an AML disease team composed of researchers across labs and clinician partners. The team’s research falls into several large categories, including studying the genetics of AML, studying how the disease works in animal models and working to develop drugs that can target specific mutations associated with the disease, which are numerous. 

“AML has many different subtypes, so it’s been difficult for researchers to make major advances to treat all cases of AML,” says Deshpande, who co-leads the AML team with Professor Peter D. Adams, PhD “Most patients with AML are given the same treatments that have been used since the ’70s, which is why we want to look at AML from as many angles as possible.”

In addition to being difficult to treat, it is also challenging to get funding for AML research, particularly for the rarer subtypes. This makes the support of foundations such as LTJF even more vital to researchers like Deshpande. 

“This is exactly why AML research needs more support and needs more funding, because this is a much more difficult disease than other forms of leukemia,” says Todd. “Many patients don’t have positive outcomes, and the only way to turn that pendulum is to intensify our efforts and increase the amount of research being done.”

Institute News

Top Sanford Burnham Prebys research stories of 2021

AuthorSusan Gammon
Date

December 14, 2021

This year’s most popular research stories include scientific breakthroughs in COVID-19, cancer, schizophrenia and more.

As we bid farewell to 2021, let’s celebrate our most newsworthy research breakthroughs. Despite the continuing challenges brought on by COVID-19, Sanford Burnham Prebys achieved important milestones on the frontiers of biomedical science.

The following 10 research-related stories received top views on Newswise—the press release distribution service for journalists seeking health and science news.
 

  1. COVID-19: Scientists identify human genes that fight infection


    A research team was able to pinpoint specific human genes that control viral infection. The information sheds new light on factors that lead to severe disease and guides therapeutic options.
     
  2. Tumor marker may help overcome endocrine treatment-resistant breast cancer


    The study discovered a new approach to select breast cancer patients for HER2 therapy and could help individuals avoid disease relapse or progression of endocrine-sensitive disease.
     
  3. Scientists identify potential drug candidates for deadly pediatric leukemia


    Two existing drugs—JAK inhibitors and Mepron—show promise for a subtype of acute myeloid leukemia (AML) that is more common in children. The drugs are proven safe in humans, which could accelerate clinical studies.
     
  4. Leprosy drug holds promise as at-home treatment for COVID-19


    Scientists found that the leprosy drug clofazimine, which is FDA approved and on the World Health Organization’s List of Essential Medicines, exhibits potent antiviral activities against SARS-CoV-2, and could become an important weapon against future pandemics.
     
  5. Researchers dig deeper into how cells transport their waste for recycling


    Research describing how the “trash bags” in a cell—called autophagosomes—are tagged for recycling opened new paths to understand age-related diseases such as cancer and neurological disorders.
     
  6. New drug combination shows promise as powerful treatment for AML


    Researchers identified two drugs that are potent against acute myeloid leukemia (AML) when combined, but only weakly effective when used alone. The study provides a scientific rationale for advancing clinical studies of the drug combination.
     
  7. Biomarker could help diagnose schizophrenia at an early age


    A study described how elevated levels of a protein called CRMP2—found in the brain and blood—could become a format for a rapid, minimally invasive blood test to support the diagnosis of schizophrenia.
     
  8. Scientists identify “immune cop” that detects SARS-CoV-2


    Researchers discovered the sensor in human lungs that detects SARS-CoV-2 and signals that it’s time to mount an antiviral attack. The sensor activates interferon, the body’s own frontline defender against viral invasion.
     
  9. Study finds promising therapeutic target for colitis


    Scientists identified an enzyme in the gut that triggers an inflammatory cascade leading to colitis. Therapeutically targeting the enzyme may be a viable approach to help the millions of people worldwide affected by the disorder.
     
  10. Scientists shrink pancreatic tumors by starving their cellular “neighbors”


    For the first time, blocking “cell drinking,” or micropinocytosis in the thick tissue surrounding a pancreatic tumor, was shown to slow tumor growth—providing more evidence that micropinocytosis is an important therapeutic target.
Institute News

Meet cancer researcher Karina Barbosa Guerra

AuthorMonica May
Date

February 3, 2021

Barbosa Guerra is working to find better treatments for a deadly leukemia

For Karina Barbosa Guerra, touring a lab and meeting scientists as part of her Girl Guides troop—Mexico’s equivalent of the Girl Scouts—was a life-changing experience. Suddenly, she could see herself as a scientist.

Today, Barbosa Guerra is a graduate student in the Deshpande lab at Sanford Burnham Prebys, where she’s working to find better treatments for a blood cancer called acute myeloid leukemia (AML). We caught up with Barbosa Guerra as she prepares to take the virtual stage at the Diversity and Science Lecture Series at UC San Diego (DASL) to learn more about when she decided she wanted to be a scientist and where she can be found when not in the lab.

Tell us about the moment you realized you wanted to be a scientist.
According to my mother, I stated that I wanted to become a chemist to develop vaccines when I was ten years old. However, it wasn’t until middle school that I started cultivating my own sense of scientific curiosity. At that time, I was in a Girl Scouts program centered on HIV/AIDS peer education, so I began to read a bit more about viruses. It was incredibly amazing that they could linger undetected in our bodies—and that many questions about their biology remained unanswered. The more I learned, the less I felt I knew, and I wanted to follow that endless string of questions.

What do you study, and what is your greatest hope for your research?
I study a cancer called acute myeloid leukemia—specifically, subtypes that are hard to treat. Certain cancer cells, like stem cells, are pretty resilient and can self-renew. This enables them to resist therapy, so we want to discover better ways to target this particular feature. My research aims to find ways in which we can treat these leukemias based on their stem cell–like capabilities. My hope is that we can ultimately benefit the patients enduring harsh treatments and disease relapse, and along the way, illuminate the fascinating aspects of the biology behind effective treatments.

What do you wish people knew about science?
That it’s a team effort. The current coronavirus pandemic has really shown us that collaboration is at the heart of transformative science. I think that great ideas are best developed through discussion—and the thrill of putting the pieces together is way more enjoyable with company.

How do you think your lab colleagues would describe you?
Maybe as the girl with a bunch of notebooks. I like to make notes of everything. My notebooks are way more reliable than my memory.

What is the best career advice you’ve ever received?
Early in the graduate program, one of my mentors told me, “Be there,” meaning that I had to spend time with my science. If I were to discover something or make a great insight, I had to be there to do it, think it or see it.

What do you wish people knew about Sanford Burnham Prebys?
That this is such a welcoming community. I felt this the very first time I visited the campus, and I feel so at home here as a student. There are plenty of opportunities to engage with others and help each other out. I really enjoy the collaborative spirit of our little community.

Learn more about the Institute’s Graduate School of Biomedical Sciences.

Institute News

“We are desperate for new therapies”

AuthorMonica May
Date

September 23, 2019

Experts discuss AML during the Sanford Burnham Prebys community lecture series 

Bill Veljovich had never been sick in his life. “Not even joint pain,” shared the 80-year-old retired engineer at our recent Fleet Science Center discussion about acute myeloid leukemia (AML), a life-threatening type of blood cancer. He was joined by experts from Sanford Burnham Prebys and UC San Diego Health.
 
However, his doctor noticed that his white blood cells counts were off during a routine blood test. He was diagnosed with a blood cancer called myelodysplastic syndrome (MDS), which progressed to AML (this occurs in one out of three people with MDS). Fortunately, Veljovich responded well to a then off-label treatment that only recently was approved for older patients with AML. 

“The truth is, we are desperate for new therapies,” said speaker Rafael Bejar, MD, PhD, a clinician at UC San Diego who specializes in blood cancers. “AML typically occurs in people over the age of 60, who often aren’t able to tolerate intensive chemotherapies.” 

Until two years ago, the treatments for AML remained the same as those used in the 1970s: a chemotherapy combination and perhaps a bone marrow transplant. Only 24% of adults with AML remained alive five years after treatment. 

Now, thanks to foundational research that revealed the underlying genetic drivers of AML, eight new drugs have been approved in the past two years. Several more targeted therapies are nearing potential FDA approval. 

However, AML, which usually arises in cells that turn into white blood cells, is an incredibly complex and fragmented disease. Genome sequencing has revealed that more than 30 genes drive the cancer. Many different treatment types will be needed to truly conquer AML.

Peter Adams, PhD, a professor in Sanford Burnham Prebys’ National Cancer Institute (NCI)-designated Cancer Center, hopes to find a treatment that works for a broader AML population. He focuses on a protein called p53, often called the “guardian of our genome.” This protein senses DNA damage and kills the faulty cell—protecting us from developing cancer. However, to scientists’ surprise, 90% of people with AML have a normal p53 gene. 

“Emerging research suggests that AML inactivates p53 through other means,” said Adams. “My team is working to develop a drug combination that could reactivate the protective powers of p53—and thus fight AML.”

New research advances can’t come soon enough for people living with the cancer. 

“I’ve always taken the approach of learning as much as possible—and then fixing the problem,” said Veljovich, who designed and tested rocket engines before he retired. “I have learned that blood cancers are extremely complex. I wish there was a simple solution, but there isn’t. I’m grateful that we have smart folks like Dr. Bejar and Professor Adams who are working on these tough problems to find better medicines for AML.”

This event was the second of our five-part “Cornering Cancer” series. Join us for discussions on breast cancer (October 20), pancreatic cancer (November 17) and pediatric brain cancer (December 8). Register today.

Institute News

Leukemia research breakthrough: a new way to trigger cancer cell suicide

AuthorJessica Moore
Date

May 18, 2016

Better therapies for acute myeloid leukemia (AML), a fast-growing cancer of the bone marrow, are urgently needed. Nearly 15,000 people in the United States are diagnosed with AML each year, and it’s the most common acute leukemia in adults. The cause of the disease is unknown, and it is usually fatal within the first five years. Continue reading “Leukemia research breakthrough: a new way to trigger cancer cell suicide”