News Release

Fine-tuning cell death: New component of death machinery revealed

Peer-Reviewed Publication

Walter and Eliza Hall Institute

Pore Forming in Mitochondrion (1 of 2)

video: During cell death, protein pores (purple) are formed in mitochondria, the powerhouses of cells, allowing their contents (red) to spill out. Animation clip taken from WEHI-TV's 'Apoptosis and venetoclax.' view more 

Credit: Walter and Eliza Hall Institute/WEHI-TV, Australia

An important component of the microscopic machinery that drives cell death has been identified by Walter and Eliza Hall Institute scientists.

Studying the 'pro-death' machinery that forces damaged, diseased or unwanted cells to die, the research team revealed a protein called VDAC2 was critical for the function of a key pro-death protein called Bax.

The team also showed VDAC2 contributed to the killing of certain cancer cells by anti-cancer agents. The research, published today in the journal Nature Communications, was led by PhD student Dr Hui-San Chin with Professor David Huang, Dr Mark van Delft and Associate Professor Grant Dewson.

AT A GLANCE

  • The death of cells by a process called apoptosis is essential for the removal of unwanted, damaged or diseased cells, and is driven by a finely tuned protein 'machine'.
  • The protein Bax is a key component of the cell death machinery, forming part of a complex that takes cells to a 'point of no return' in apoptotic death.
  • Our researchers discovered a protein called VDAC2 helps Bax to drive apoptosis, and may have a role in fine-tuning cancer cells' response to anti-cancer agents.

DEATH MACHINERY

Apoptotic cell death is critical for the development and maintenance of our body, and faults in the protein machinery that drives apoptosis have been linked to a range of diseases. Faulty cell death proteins have been linked to both the development of cancer, as well as resistance of cancer cells to treatment.

A key protein in the cell death machinery is called Bax, Dr van Delft said. "Bax helps to take a cell to a 'point of no return' when apoptotic cell death is triggered, forming pores in mitochondria, the powerhouses of the cell. This unleashes the final 'executioner' proteins that dismantle a cell.

"Understanding how Bax functions could lead to new therapeutics that either promote cell death - with applications for diseases such as cancer - or therapeutics that prevent cell death, which have the potential to save cells in conditions such as neurodegenerative disorders or stroke," he said.

The team investigated how Bax and a related protein called Bak kill cells, knocking out the function of different genes using CRISPR technology, Associate Professor Dewson said.

"To our surprise we discovered a gene that was essential for the function of Bax but not Bak, despite these two proteins being functionally and structurally very similar.

"We were able to follow up on this research to show that the protein, called VDAC2, was a catalyst that helped Bax associate with mitochondria and form pores in their membranes, to kill the cell," Associate Professor Dewson said. "Intriguingly VDAC2's 'day job' is to maintain the function of the mitochondria, pumping metabolites in and out of the mitochondria."

DRIVING CANCER CELLS TO DEATH

A failure of the cell death machinery is a hallmark of cancer cells, and is linked to the resistance of cancer cells to anti-cancer treatments, said Professor Huang.

"Bax is important for helping anti-cancer agents kill cells - without Bax and its relative Bak, cancer cells cannot undergo apoptosis when treated with a range of anti-cancer therapies.

"Our research showed that VDAC2 is required for Bax to drive the response of cancer cells to conventional chemotherapy agents as well as the recently developed BH3-mimetics," Professor Huang said.

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The research was supported by the Australian National Health and Medical Research Council, the Australian Research Council, Cancer Council Victoria, the Australian Cancer Research Foundation, the Leukaemia and Lymphoma Society (US) and the Victorian Government. Dr Hui San Chin was supported by a PhD scholarship from the University of Melbourne.


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