Nanobodies identify an activated state of the TRIB2 pseudokinase

The Drosophila pseudokinase Tribbles translocates to the fat body membrane in response to fasting to modulate insulin sensitivity

The Drosophila pseudokinase Tribbles (Trbl) shares conserved functions with human TRIB3 to bind and inhibit Akt phosphorylation-activation by the Insulin Receptor (InR) to reduce insulin responses; consistent with this, increased levels of human TRIB3 are linked to type 2 diabetes. Here, we show that in fat body cells of well-fed Drosophila larvae, Trbl expression is low and predominantly in the nucleus while fasting or genetic reduction of insulin signaling resulted in increased Trbl expression and Trbl protein translocation to the plasma membrane. An E/G mutation in the Trbl pseudokinase kinase activation loop dominantly interfered with Trbl function leading to increased Akt activity, increased stability of Trbl substrates, including Trbl itself, and aberrant redistribution of Trbl multimers to the membrane. Several strategies designed to increase Akt activity were sufficient to translocate Trbl to the membrane, consistent with the notion that subcellular trafficking of Trbl to the fat body cell membrane acts a rheostat to reduce the strength of Akt-mediated insulin responses, counter to the InR, which has been shown to redistribute away from the membrane to modulate insulin signaling.

DET1 dynamics underlie cooperative ubiquitination by CRL4DET1-COP1 complexes

Transcription factor ubiquitination is a decisive regulator of growth and development. The DET1-DDB1-DDA1 (DDD) complex associates with the Cullin-4 ubiquitin ligase (CRL4) and a second ubiquitin ligase, COP1, to control ubiquitination of transcription factors involved in neurological, metabolic, and immune cell development. Here, we report the structure of the human DDD complex, revealing a specific segment of DET1 that can recruit ubiquitin-conjugating (E2) enzymes. Structural variability analysis, mass spectrometry, and mutagenesis based on AlphaFold predictions suggest that dynamic closure of DET1, stabilized by DDA1, underlies coordinated recruitment of E2 enzymes and COP1. Biochemical assays suggest that the E2 acts as a recruitment factor to bring COP1 to DET1 for more effective substrate ubiquitination, which parallels a catalytically inactive E2 enzyme (COP10) in plant DDD complexes. This work provides a clear architecture for regulation and cooperative CRL4DET1-COP1 complex assembly, which can affect degradation of diverse targets by COP1 complexes.

The role of tribbles homolog 2 in cell proliferation

Tribbles homolog 2 (TRIB2), a pseudoserine/threonine kinase, is a member of the TRIB family. TRIB2 primarily regulates cell proliferation through its scaffold or adaptor effect on promoting the degradation of target proteins by E3 ligase-dependent ubiquitination and regulating mitogen-activated protein kinase (MAPK) and protein kinase B (AKT) signaling pathways. TRIB2 is not only involved in the physiological proliferation of cells (granulosa cells, myoblasts, naive T cells, and thymocytes) during normal development but also in the pathological proliferation of vascular smooth muscle cells and a variety of cancer cells (lung cancer cells, liver cancer cells, leukemia cells, pancreatic cancer cells, gastric cancer cells, prostate cancer cells, thyroid cancer cells, cervical cancer cells, melanoma cells, colorectal cancer cells, ovarian cancer cells and osteosarcoma cells) under disease conditions. Its expression level and functional role predominantly hinge on the specific tissue and cell type it targets. This review elucidates the specific mechanisms of TRIB2 in physiological and pathological cell proliferation from the perspective of different kinds of cells.

Discovery of the first selective and potent PROTAC degrader for the pseudokinase TRIB2

Pseudokinase TRIB2, a member of the CAMK Ser/Thr protein kinase family, regulates various cellular processes through phosphorylation-independent mechanisms. Dysregulation of TRIB2 has been implicated in promoting tumor growth, metastasis, and therapy resistance, making it a promising target for cancer treatment. In this study, we designed and synthesized a series of TRIB2 PROTAC degraders by conjugating a TRIB2 binder 1 with VHL or CRBN ligands via linkers of varying lengths and compositions. Among these compounds, 5k demonstrated potent TRIB2 degradation with a DC50 value of 16.84 nM (95 % CI: 13.66-20.64 nM) in prostate cancer PC3 cells. Mechanistic studies revealed that 5k directly interacted with TRIB2, selectively inducing its degradation through a CRBN-dependent ubiquitin-proteasomal pathway. Moreover, 5k outperformed the TRIB2 binder alone in inhibiting cell proliferation and inducing apoptosis, confirming that TRIB2 protein degradation could be a promising therapeutic strategy for TRIB2-associated cancers. Additionally, compound 5k also serves as an effective tool for probing TRIB2 biology.