Researchers find link between common enzyme and cancer prevention

Researchers find link between common enzyme and cancer prevention
The right panel is an example of a caspase-2 deficient mouse tumour cell, which has an abnormal number of chromosomes.

A common enzyme found in mammals that kills damaged cells before they become cancerous is being hailed as an important breakthrough in understanding the treatment of the disease.

Researchers from the Centre for Cancer Biology at the University of South Australia have found that a deficiency of the caspase-2 enzyme place people at a higher risk of developing tumours.

Caspase-2 is an enzyme associated with apoptosis (cell deaeth) that has now been found to target aneuploid , which often develop into tumours if not killed off.

Aneuploid cells have been dubbed the hallmark of cancer in about 90 per cent of and 85 per cent of hematopoietic neoplasias.

Research leader at the University of South Australia Sharad Kumar discovered the caspase-2 enzyme nearly 25 years ago but has only just demonstrated its link to preventing tumours in recent years. He said understanding how tumours arise, spread, and become drug resistant was critical to fighting cancer.

"Our work shows that caspase-2 is necessary and directly kills cells that have become aneuploid, so it is important to work out the mechanisms," he said.

"Aneuploidy is a feature of the majority of human tumours and is known to lead to chromosomal instability that can promote cancer onset and progression and cause drug resistance.

"The idea is that if you can somehow activate caspase-2 in cells that have become aneuploid then you should be able to kill them."

Professor Kumar said the research mainly applied to blood cancers such as leukaemia or lymphoma but could also have serious implications for other types, including liver cancer.

In two recent publications, the team demonstrated that cells with a caspase-2 deficiency had weaker apoptosis, the process by which damaged cells are killed off.

Some cells that acquired DNA damage or chromosome defects during cell division, survived, due to a block in apoptosis. These surviving cells continued to grow and divide as aneuploid cells.

The research also showed that from mice, which lacked caspase-2, accumulated many of these defective, potentially cancer-causing aneuploid cells with age.

"When we challenged mice with cancer causing agents, caspase-2 deficiency resulted in all animals developing tumours earlier. They were often more aggressive and developed ," Professor Kumar said.

Key researcher Loretta Dorstyn said understanding this process was fundamental in cancer research and would help scientists search for new cancer therapies.

"Our research focuses on how damaged cells, with abnormal chromosomes, are removed," she said.

"If a cell's normal 'stop growth' and 'cell death' signals fail, this will allow to survive and potentially become cancerous."

The team's research on caspase-2 deficiency has been published in the journals Cell Death and Disease and Oncogene respectively.


Explore further

Researchers reveal how cancer cells cope with genetic chaos

More information: S Dawar et al. Caspase-2-mediated cell death is required for deleting aneuploid cells, Oncogene (2016). DOI: 10.1038/onc.2016.423

Swati Dawar et al. Impaired haematopoietic stem cell differentiation and enhanced skewing towards myeloid progenitors in aged caspase-2-deficient mice, Cell Death and Disease (2016). DOI: 10.1038/cddis.2016.406

Journal information: Cell Death and Disease , Oncogene

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Citation: Researchers find link between common enzyme and cancer prevention (2017, January 24) retrieved 21 July 2019 from https://medicalxpress.com/news/2017-01-link-common-enzyme-cancer.html
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