Breaking the dogma: Key cell death regulator has more than one way to get the job done

Breaking the dogma: Key cell death regulator has more than one way to get the job done
Left to right: Thirumala-Devi Kanneganti, Ph.D., a member of the St. Jude Department of Immunology, with postdoctoral fellows Kesavardhana Sannula, Ph.D. and Parimal Samir, Ph.D. Credit: St. Jude Children's Research Hospital

Scientists at St. Jude Children's Research Hospital have discovered a new way that the molecule RIPK1 leads to cell death in infected, damaged or unwanted cells showing that more than one mechanism can trigger the process. The findings appeared online today in the Journal of Experimental Medicine.

"Our findings break the existing dogma that RIPK1 kinase activity is required for ," said Thirumala-Devi Kanneganti, Ph.D., a member in the St. Jude Department of Immunology.

The discovery of the alternate RIPK1 mechanism offers the promise of drug treatments to protect patients from the inflammatory, cell-killing response of septic shock and other as well as cancer.

'Cleaning house' by triggering cell death

The immune system protects the body and rids itself of unwanted cells in health and disease through three major programmed cell-death mechanisms, called pyroptosis, apoptosis and necroptosis. Kanneganti's lab has dubbed the processes collectively PANoptosis.

Kanneganti and her colleagues had shown that RIPK1 kinase activity functions as a cell switch to activate PANoptosis. RIPK1 triggers this form of cell death when cell survival molecules such as TAK1 are inhibited. TAK1's function is central to the body's protection against a broad range of bacteria, viruses and other agents. Pathogens have evolved to inhibit TAK1 in order to evade the .

Researchers developed a model system to study the phenomenon. The investigators selectively blocked TAK1 and the RIPK1 kinase function in called macrophages that were exposed to microbial molecules.

Despite the loss of RIPK1 kinase function, the cells reacted as if the immune system had been activated. TAK1 deletion or inhibition triggered cell death. "The results showed the immune system recognizes loss of TAK1 function as a danger signal," Kanneganti said. "That drives the robust inflammation and cell death of PANoptosis with the goal of fighting infection."

But the enhanced inflammation and sensitivity to cell death left mice with altered macrophages at greater susceptibility to septic shock.

Dual mechanisms of action

To the researchers' surprise, their experiments identified a separate route to RIPK1 activation—in which the molecule acts as a "scaffold" to support a separate molecular mechanism that triggers PANoptosis. Their work demonstrated how PANoptosis can be triggered even when RIPK1's kinase activity is inactivated.

"We highlight for the first time a kinase-independent role for RIPK1 in promoting a novel and versatile cell death complex which drives PANoptosis, the cell death pathways involved in several inflammatory disorders," Kanneganti said. "Dysregulation of this complex can lead to severe diseases, including septic shock. Our work underscores the importance of investigating the homeostatic molecular mechanisms of inflammatory cell in health and disease."

The findings also offer the potential of drugs that could trigger PANoptotic cell suicide in proliferating cancer . Such drug treatments could aid cancer immunotherapy, in which a patient's own is activated to attack tumors.

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More information: R.K. Subbarao Malireddi et al, Innate immune priming in the absence of TAK1 drives RIPK1 kinase activity–independent pyroptosis, apoptosis, necroptosis, and inflammatory disease, The Journal of Experimental Medicine (2019). DOI: 10.1084/jem.20191644
Journal information: Journal of Experimental Medicine

Citation: Breaking the dogma: Key cell death regulator has more than one way to get the job done (2019, December 23) retrieved 31 July 2021 from
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