PAC-1

Density functional theory calculations confirmed their enhanced zinc-binding affinity, with adsorption energies (Eads) of -14.8332 eV (F17) and -14.8797 eV (F21), compared to -12.7474 eV for PAC-1, along with stronger electrostatic potential minima (-67.20 and -66.99 kcal/mol, respectively)...Importantly, in vivo neurotoxicity assessments revealed no significant neuronal damage at doses up to 50 mg/kg, underscoring their improved safety profile over earlier activators. These results establish F21 as a particularly promising preclinical candidate and provide a rational framework for developing target-specific, neurotoxicity-sparing procaspase-3 activators for TNBC therapy.

Consequently, PAC-1 induces progressive iron depletion and selective cytotoxicity in otherwise drug-resistant MDR1-expressing cancer cells. Together, these findings redefine PAC-1's mechanism-of-action and establish a framework for exploiting multidrug resistance as a therapeutic vulnerability through targeted iron starvation.

Combining tumor necrosis factor-related apoptosis-inducing ligand (TRAIL)-producing oncolytic viruses with procaspase-3 activator (PAC-1) presents a promising therapeutic strategy, as TRAIL initiates apoptosis while PAC-1 amplifies caspase activity...This integrative approach provides mechanistic insight into tumor behavior while improving predictive accuracy, supporting the development of personalized therapeutic strategies for GCTs. The framework also offers broader applicability to other cancers with limited treatment options and heterogeneous responses.

By hybridizing this natural product scaffold with optimized structural elements from PAC-1, a reference procaspase-3 activator, 28 target compounds (K-01 ∼ K-28) were successfully synthesized...These results demonstrate that the hybrid molecular design strategy effectively combines the pharmacophoric advantages of both natural products and synthetic activators. The developed procaspase-3 activators exhibit improved therapeutic potential and represent promising candidates for further development as targeted anticancer agents modulating the caspase-3 activation pathway.

ImmuProgML offers a promising avenue for understanding the intricate relationship between tumors and the immune system, providing a machine learning framework for personalized cancer immunotherapy selections.

Our data show that PAC-1 modulates sunitinib-induced autophagy and blocks lysosomal trapping, potentiating sunitinib activity and increasing death of cancer cells. As both drugs are well-tolerated in patients, the data suggest evaluation of the PAC-1/sunitinib combination in a clinical trial of patients with PNET.

Drug sensitivity analysis identified specific drugs, including PAC-1, SNX-2112, BELINOSTAT, VORINOSTAT, TPCA-1, and PHA-893,888, whose efficacy may be influenced by PTPN6 expression. Knocking down PTPN6 expression inhibited the proliferation and migration of colorectal cancer cells in vitro, confirming its oncogenic role in this cancer type. This pan-cancer analysis establishes PTPN6's multifaceted influence on tumor immunity and its potential as a biomarker and therapeutic target.

In addition, relative expression levels of von Willebrand Factor, β-TG, and iNOS and serum concentrations of PAC-1, β-TG, and iNOS were inhibited. Sodium ferulate can treat AAV by inhibiting NET release and platelet activation and reducing endothelial cell damage.

Drug sensitivity analysis further demonstrated that tumors with elevated pyrimidine metabolism displayed increased responsiveness to several chemotherapeutic agents, including BI-2536, JW-7-24-1, and PAC-1, suggesting that targeting pyrimidine metabolism may enhance treatment efficacy. In conclusion, pyrimidine metabolism plays a critical role in prostate cancer progression, influencing immune infiltration and drug sensitivity. Targeting this metabolic pathway offers a promising strategy for the development of new therapeutic approaches, particularly for overcoming drug resistance and improving outcomes in patients with advanced prostate cancer.

Derived from PAC-1, SM-1 can activate procaspase-3 and induce apoptosis in cancer cells to exert anti-tumor effects...Meanwhile, anti-tumor effect of SM-1 on HNSCC was higher than that of Debio1143, and the radiosensitivity of cells was greatly increased...In vivo, SM-1 combined irradiation showed a good anti-tumor effect. SM-1 enhances HNSCC cell radiation sensitivity in vitro and in vivo, supporting its potential as a radiosensitizer for clinical trials in combination with radiotherapy.

Prophylactic transfusion improved platelet function. Platelet function significantly improved in patients with a CCI >4500, those with the same blood types as that of apheresis platelets, or those with platelet-derived microparticle levels <4.7%. No significant improvement in platelet function was noted after the transfusion of different blood types with acceptable compatibility or the transfusion of incompatible blood types. Our results suggest that transfusing platelets with the same blood type remains the optimal choice.

A platelet aggregation assay was performed, and the expression of P-selectin and PAC-1, as well as the effect on the proliferation of healthy endothelial cells, were evaluated. All the analogues reduced the expression of E- and N-cadherin in different amounts, while the analogues-1 and -3 exhibited similar antimigratory effects on HepG2 cells. The results of this study reveal considerable potential to develop new tyrosine kinase inhibitors with improved antiplatelet and antitumor properties.