News Release

Pancreatic cancer hijacks a brain-building protein

Peer-Reviewed Publication

Cold Spring Harbor Laboratory

PDAC tumors

image: 

Pancreatic ductal adenocarcinoma (PDAC) can spread like wildfire with the help of a protein called Engrailed-1. Above: PDAC tumors (dark purple) that have taken root in the lungs of mice.

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Credit: Tuveson lab/Cold Spring Harbor Laboratory

Scientists at Cold Spring Harbor Laboratory (CSHL) and the University of California, Davis have reached a new breakthrough in pancreatic cancer research—eight years in the making. It could help slow the disease’s deadly spread.

In 2017, as a postdoc in CSHL’s Tuveson lab, Chang-il Hwang and collaborators from the Vakoc lab uncovered a protein essential for jumpstarting metastasis in pancreatic ductal adenocarcinoma (PDAC). Now an assistant professor at UC Davis, Hwang recently reunited with CSHL Professors David Tuveson and Christopher Vakoc. The trio once again set their sights on PDAC. The disease is known for its aggressiveness. It often spreads to other organs like wildfire, wreaking havoc in its path.

“Metastatic spread is one of the reasons pancreatic cancer is such a deadly disease,” Vakoc says. “Our study led by Dr. Hwang has opened the door to new insights we might one day use to combat aggressive PDAC.”

The team found that late-stage PDAC hijacks a protein called Engrailed-1 (EN-1) to evade the body’s natural cancer defenses. EN-1 is a type of protein known as a transcription factor. These proteins control the timing and duration of gene expression. This particular transcription factor is required to form major areas of the brain.

“EN-1 is known to play a role in neurodevelopment,” Hwang explains. “In the pancreas, it’s not normally expressed. But in the later stages of pancreatic cancer, it gets overly expressed and makes the cancer more metastatic.” That means a faster, deadlier spread. But what if EN-1 could be targeted in cancer? Hwang, Tuveson, and Vakoc sought to find out.

The team used organoids—mini versions of tumors—to identify the role of over-expressed EN-1 in PDAC. They found that higher levels of the aberrant protein blocked genes associated with natural cell death. When EN-1 expression was curtailed, the genes it targets were able to do their job, promoting healthy cell survival.

“Without EN-1, cancer progression slows,” Hwang says. “At the moment, it’s hard to target transcription factors with drugs. But in the future, it may be possible to disrupt the kind of interactions we see with mutated EN-1 in PDAC.”

Pancreatic cancer remains the third-leading cause of cancer-related deaths in the U.S. Hwang plans to continue collaborating with CSHL in hopes that his team’s work may lead to better treatments.

“We know certain types of PDAC are dependent on EN-1,” Hwang says. “If we can develop a way to test for it, we can create more personalized therapeutics and treatment strategies for patients. We’re looking forward to heading in that direction.”


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