The innate immune system is intrinsically fascinating, dealing with invaders long before antibodies or cytotoxic cells are on the scene. It is even more fascinating to a chemist because it works in part by forming amyloid inside the cell. And you thought amyloid was bad.
The system becomes even more fascinating because blocking one part of it (RIPK1) may be a way to treat a variety of neurologic diseases (ALS, MS,Alzheimer’s, Parkinsonism) whose treatment could be improved to put it mildly.
One way to deal with an invader which has made it inside the cell, is for the cell to purposely die. More and more it appears that many forms of cell death are elaborately programmed (like taking down a stage set).
Necroptosis is one such, distinct from the better known and studied apoptosis. It is programmed and occurs when a cytokine such as tumor necrosis factor binds to its receptor, or when an invader binds to members of the innate immune system (TLR3, TLR4).
The system is insanely complicated. Here is a taste from a superb review — unfortunately probably behind a paywall — https://www.pnas.org/content/116/20/9714 — PNAS vol. 116 pp. 9714 – 9722 ’19.
“RIPK1 is a multidomain protein comprising an N-terminal kinase domain, an intermediate domain, and a C-terminal death domain (DD). The intermediate domain of RIPK1 contains an RHIM [receptor interacting protein (rip) homotypic interaction motif] domain which is important for interacting with other RHIM-containing proteins such as RIPK3, TRIF, and ZBP1. The C-terminal DD mediates its recruitment by interacting with other DD-containing proteins, such as TNFR1 and FADD, and its homodimerization to promote the activation of the N-terminal kinase domain. In the case of TNF-α signaling, ligand-induced TNFR1 trimerization leads to the assembly of a large receptor-bound signaling complex, termed Complex I, which includes multiple adaptors (TRADD, TRAF2, and RIPK1), and E3 ubiquitin ligases (cIAP1/2, LUBAC complex).”
Got that? Here’s a bit more
“RIPK1 is regulated by multiple posttranslational modifications, but one of the most critical regulatory mechanisms is via ubiquitination. The E3 ubiquitin ligases cIAP1/2 are recruited into Complex I with the help of TRAF2 to mediate RIPK1 K63 ubiquitination. K63 ubiquitination of RIPK1 by cIAP1/2 promotes the recruitment and activation of TAK1 kinase through the polyubiquitin binding adaptors TAB2/TAB3. K63 ubiquitination also facilitates the recruitment of the LUBAC complex, which in turn performs M1- type ubiquitination of RIPK1 and TNFR1. M1 ubiquitination of Complex I is important for the recruitment of the trimeric IκB kinase complex (IKK) through a polyubuiquitin-binding adaptor subunit IKKγ/NEMO . The activation of RIPK1 is inhibited by direct phosphorylation by TAK1, IKKα/β, MK2, and TBK1. cIAP1 was also found to mediate K48 ubiquitination of RIPK1, inhibiting its catalytic activity and promoting degradation.”
So why should you plow through all this? Because inhibiting RIPK1 reduces oxygen/glucose deprivation induced cell death in neurons, and reduced infarct size in experimental middle cerebral artery occlusion.
RIPK1 is elevated in MS brain, and inhibition of it helps an animal model (EAE). Mutations in optineurin, and TBK1 leading to familial ALS promote the onset of RIPK1 necroptosis
Inflammation is seen in a variety of neurologic diseases (Alzheimer’s, MS) and RIPK1 is elevated in them.
Inhibitors of RIPK1 are available and do get into the brain. As of now two RIPK1 inhibitors have made it through phase I human safety trials.
So it’s time to try RIPK1 inhibitors in these diseases. It is an entirely new approach to them. Even if it works only in one disease it would be worth it.
Now a dose of cynicism. Diseased cells have to die one way or another. RIPK1 may help this along, but it tells us nothing about what caused RIPK1 to become activated. It may be a biomarker of a diseased cell. The animal models are suggestive (as they always are) but few of them have panned out when applied to man.
