SPIN1 (Spindlin 1)

Functionality was confirmed by a pulldown assay with a known interacting partner, Spindlin1. This protocol provides a robust framework to obtain untagged HBx1-120 for structural and functional in vitro studies.

The review explores the structural characteristics of various Tudor domains, their binding preferences for specific histone modifications, and the consequences of these interactions for leukemia. By providing a comprehensive overview of current research, this review underscores the therapeutic potential of Tudor domain-targeting strategies in leukemia and emphasizes the need for further development of epigenetics-based treatment strategies to address resistance and relapse in these malignancies.

Low SPIN1 expression group could benefit from Axitinib, Cytarabine, Pazopanib and Sunitinib. Finally, we screened the 10 genes with the strongest correlation with SPIN1, among which CDH11 and SLC8A1 were associated with the prognosis of GC. In conclusion, our study has provided valuable insights into the pivotal role of SPIN1 in GC development, elucidating its potential molecular mechanisms and establishing it as a promising therapeutic target.

In conclusion, the inhibition of Spindlin-1 had only minor effects on polarization of macrophages and T cell proliferation but profoundly prevented B cell activation at low concentrations. This suggests that Spindlin-1 inhibitors, while mediating anticancerogenic effects, may also suppress the humoral immune response and increase infection risk.

In addition, through virtual screening and molecular docking, a new lead compound CXY49 was found presenting an effective binding to SPIN1. The structural and energetic changes identified in this study provide valuable insights for the development of new SPIN1 inhibitors.

Moreover, restoration of FOXM1 expression markedly abolished the inhibitory effects and increased radiosensitivity induced by SPIN1 depletion. These results indicate that the SPIN1-MDM2-FOXO3a/FOXM1 signalling axis is essential for NSCLC progression and radioresistance and could serve as a therapeutic target for increasing radiotherapy efficacy.

We also show that SPIN1 increases chemoresistance. These findings reveal a novel role for SPIN1 in the activation of H3K9me3-dependent DNA repair pathways, and suggest that SPIN1 may contribute to cancer chemoresistance by modulating the efficiency of double-strand break (DSB) repair.

These findings provide new insights into the biological function of the IDR in regulating SPIN1 activity and reveal a previously unrecognized role of SPIN1-IDR in histone methylation readout. Our study uncovers the crucial role of appropriate biophysical properties of SPIN1 in facilitating gene expression and links phase separation to tumorigenesis, which provides a new perspective for understanding the function of SPIN1.

Further, circ_0081069-Exo inhibited radiosensitivity in ESCC cells. Exosome-mediated transfer of circ_0081069 induced SPIN1 production by binding to miR-195-5p, further inhibiting radiosensitivity in ESCC.

miR-3133 inhibits GIC progression by activating the Hippo and p53 signalling pathways via multi-targets, including RNF146, thereby providing prognostic factors and valuable potential therapeutic targets for GIC.