Acute myeloid leukemia (AML), an aggressive hematological disease that causes uncontrolled accumulation of white blood cells, is one of the most common types of leukemia in adults. However, AML is still fairly rare overall, accounting for only about 1% of all diagnosed cancers.  Generally, AML is a disease of older people and is uncommon before the age of 45. The average age of people when they are first diagnosed with AML is about 68. But AML can occur in children as well.[1][2]

Because of the poor outcomes of this disease, researchers across the globe have been on the hunt for new ways to treat AML, while preserving normal blood development.

Researchers at Baylor College of Medicine and collaborating institutions report in the journal Cancer Research a new vulnerability of this cancer that can be targeted with a class of experimental drugs. These drugs target a protein complex called SWI/SNF, which many cells use to make DNA more open and accessible. DNA accessibility heavily influences gene expression by controlling what is known as the epigenetic state of the cell. [3]

The authors of the study, supported by grants from the Gabrielle’s Angel Foundation, the V Foundation, the Mark Foundation for Cancer Research (20–024-ASP), and the Adrienne Helis Malvin Medical Research Foundation, show that drugs inhibiting SWI/SNF induce a profound therapeutic response in AML cell lines, animal models and human AML samples. In animals, this strategy caused rapid regression of the cancer within days. When authors compared their findings against AML cells to normal blood cells, they found that the drug targeting SWI/SNF caused specific changes to blood development. However, these side effects were manageable and quickly reversed after drug treatment.


The results support further investigations on the use of this approach for AML.

Advertisement #3
H. Courtney Hodges, Ph.D. is Assistant Professor, Department of Molecular and Cellular Biology Center for Precision Environmental Health Baylor College of Medicine.

“Our project set out to better understand a vulnerability in AML that could be exploited to treat the disease,” explained corresponding author, H. Courtney Hodges, Ph.D., assistant professor of molecular and cellular biology and member of the Dan L Duncan Comprehensive Cancer Center at Baylor.

Hijacking a Gene Regulation Program
In the course of the study, the scientists also discovered important mechanisms related to SWI/SNF.

“We found that AML cells hijack a gene regulation program that involves SWI/SNF and another protein called PU.1. This program is normally used to make healthy white blood cells,” said first author Courtney Chambers, a graduate student in the Hodges lab.

“Think of each cell’s DNA as a huge labyrinth with many doors behind which are genes that contain instructions on how to make proteins,” Hodges explained.

“Most of these doors do not lead to genes of interest to a blood cell, so these cells need a way to know which doors lead to the specific genes they need. Here is where PU.1 plays a role.”

“We found that PU.1 flags the doors that lead to genes of interest to certain blood cells,” Chambers added.

“In the case of AML cells, these flags mark genes that promote growth of AML, called oncogenes. PU.1 tags the doors but cannot open them, so SWI/SNF comes along.”

Courtney Chambers is a Postdoc Fellow at Baylor College of Medicine’s Center for Precision Environmental Health.

SWI/SNF is a protein complex that mediates access to DNA. After PU.1 tags a site of interest, SWI/SNF steps in and opens that door allowing expression of the oncogenes that sustain AML. The team found that some AML samples are much more dependent on this mechanism than normal blood cells.

Importantly, the researchers also discovered that drugs that block SWI/SNF’s ability to open the door to gene activation in AML halt tumor growth by interfering with the expression of these oncogenes.

“It was very exciting to see how effective SWI/SNF inhibitors were to treat AML in animal models,” Chambers said. “The effect was much more profound than we had expected.”

“AML is typically very hard to treat. The rapid tumor regression we saw in response to SWI/SNF inhibitors has encouraged us to continue our research into similar vulnerabilities of AML and other cancers,” Hodges concluded.

[1] Key Statistics for Acute Myeloid Leukemia (AML). American Cancer Society (ACS). Online. Last accesses on April 4, 2023
[2] Leukemia in Chidren. American Cancer Society. Online. Last accesses on April 4, 2023.
[3] Chambers C, Cermakova K, Chan YS, Kurtz K, Wohlan K, Lewis AH, Wang C, Pham A, Dejmek M, Sala M, Loeza Cabrera M, Aguilar R, Nencka R, Lacorazza HD, Rau RE, Hodges HC. SWI/SNF Blockade Disrupts PU.1-Directed Enhancer Programs in Normal Hematopoietic Cells and Acute Myeloid Leukemia. Cancer Res. 2023 Apr 4;83(7):983-996. doi: 10.1158/0008-5472.CAN-22-2129. PMID: 36662812; PMCID: PMC10071820.

Advertisement #5