Dysregulated Epiregulin(EREG)can activate epidermal growth factor receptor(EGFR)and promote tumor progression in head and neck squamous cell carcinoma(HNSCC).However,the mechanisms underlying EREG dysregulation remain largely unknown.Here,we showed that dysregulated EREG was highly associated with enhanced PDL1 in HNSCC tissues.Treatment of HNSCC cells with EREG resulted in upregulated PDL1 via the c-myc pathway.Of note,we found that N-glycosylation of EREG was essential for its stability,membrane location,biological function,and upregulation of its downstream target PDL1 in HNSCC.EREG was glycosylated at N47 via STT3B glycosyltransferases,whereas mutations at N47 site abrogated N-glycosylation and destabilized EREG.Consistently,knockdown of STT3B suppressed glycosylated EREG and inhibited PDL1 in HNSCC cells.Moreover,treatment of HNSCC cells with NGI-1,an inhibitor of STT3B,blocked STT3B-mediated glycosylation of EREG,leading to its degradation and suppression of PDL1.Finally,combination of NGI-1 treatment with anti-PDLl therapy synergistically enhanced the efficacy of immunotherapy of HNSCC in vivo.Taken together,STT3B-mediated N-glycosylation is essential for stabilization of EREG,which mediates PDL1 upregulation and immune evasion in HNSCC.

Dysregulated Epiregulin(EREG)can activate epidermal growth factor receptor(EGFR)and promote tumor progression in head and neck squamous cell carcinoma(HNSCC).However,the mechanisms underlying EREG dysregulation remain largely unknown.Here,we showed that dysregulated EREG was highly associated with enhanced PDL1 in HNSCC tissues.Treatment of HNSCC cells with EREG resulted in upregulated PDL1 via the c-myc pathway.Of note,we found that N-glycosylation of EREG was essential for its stability,membrane location,biological function,and upregulation of its downstream target PDL1 in HNSCC.EREG was glycosylated at N47 via STT3B glycosyltransferases,whereas mutations at N47 site abrogated N-glycosylation and destabilized EREG.Consistently,knockdown of STT3B suppressed glycosylated EREG and inhibited PDL1 in HNSCC cells.Moreover,treatment of HNSCC cells with NGI-1,an inhibitor of STT3B,blocked STT3B-mediated glycosylation of EREG,leading to its degradation and suppression of PDL1.Finally,combination of NGI-1 treatment with anti-PDLl therapy synergistically enhanced the efficacy of immunotherapy of HNSCC in vivo.Taken together,STT3B-mediated N-glycosylation is essential for stabilization of EREG,which mediates PDL1 upregulation and immune evasion in HNSCC.

Objective A practical and highly accurate algorithm for dynamic monitoring of plantar pressure was proposed, the magnitude of vertical ground reaction force (vGRF) during walking was measured by a capacitive insole sensor, and reliability of the prediction accuracy was verified. Methods Four healthy male subjects were require to wear capacitive insole sensors, and their fast walking and slow walking data were collected by Kistler three-dimensional (3D) force platform. The data collected by the capacitive insole sensors were pixelated, and then the processed data were fed into a residual neural network, ResNet18, to obtain high-precision vGRF. Results Compared with analysis of the data collected from Kister force platform, the normalized root mean square error (NRMSE) for fast walking and slow walking were 8.40% and 6.54%, respectively, and the Pearman correlation coefficient was larger than 0.96. Conclusions This study provides a novel algorithm for dynamic measurement of GRF in mobile scenarios, which can be used for estimation of complete GRF outside the laboratory without being constrained by the number and location of force plates. Potential application areas include gait analysis and efficient capture of pathological gaits.