Changming Lu
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View article: Figure S5 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
Figure S5 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy Open
Supplemental Figure S5
View article: Figure S1 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
Figure S1 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy Open
Supplemental Figure S1
View article: Table S1 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
Table S1 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy Open
Supplemental Table S1
View article: Figure S6 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
Figure S6 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy Open
Supplemental FigureS6
View article: Figure S2 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
Figure S2 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy Open
Supplemental Figure S2
View article: Table S1 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
Table S1 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy Open
Supplemental Table S1
View article: Figure S4 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
Figure S4 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy Open
Supplemental Figure S4
View article: Data from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
Data from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy Open
Programmed cell death 1 ligand 1 (PD-L1) is a key driver of tumor-mediated immune suppression, and targeting it with antibodies can induce therapeutic responses. Given the costs and associated toxicity of PD-L1 blockade, alternative therap…
View article: Figure S1 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
Figure S1 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy Open
Supplemental Figure S1
View article: Figure S3 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
Figure S3 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy Open
Supplemental Figure S3
View article: Figure S5 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
Figure S5 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy Open
Supplemental Figure S5
View article: Data from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
Data from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy Open
Programmed cell death 1 ligand 1 (PD-L1) is a key driver of tumor-mediated immune suppression, and targeting it with antibodies can induce therapeutic responses. Given the costs and associated toxicity of PD-L1 blockade, alternative therap…
View article: Figure S3 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
Figure S3 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy Open
Supplemental Figure S3
View article: Figure S4 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
Figure S4 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy Open
Supplemental Figure S4
View article: Figure S6 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
Figure S6 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy Open
Supplemental FigureS6
View article: Figure S2 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
Figure S2 from Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy Open
Supplemental Figure S2
View article: Data from Silencing of <i>CD24</i> Enhances the PRIMA-1–Induced Restoration of Mutant p53 in Prostate Cancer Cells
Data from Silencing of <i>CD24</i> Enhances the PRIMA-1–Induced Restoration of Mutant p53 in Prostate Cancer Cells Open
Purpose: In prostate cancer cells, there is CD24-dependent inactivation of mutant p53, but the mechanism and its significance remain largely unknown. Here, we validated this observation and explored the therapeutic potential of targeting C…
View article: Data from Silencing of <i>CD24</i> Enhances the PRIMA-1–Induced Restoration of Mutant p53 in Prostate Cancer Cells
Data from Silencing of <i>CD24</i> Enhances the PRIMA-1–Induced Restoration of Mutant p53 in Prostate Cancer Cells Open
Purpose: In prostate cancer cells, there is CD24-dependent inactivation of mutant p53, but the mechanism and its significance remain largely unknown. Here, we validated this observation and explored the therapeutic potential of targeting C…
View article: Supplementary Figures 1-4 and Tables 1-4 from Silencing of <i>CD24</i> Enhances the PRIMA-1–Induced Restoration of Mutant p53 in Prostate Cancer Cells
Supplementary Figures 1-4 and Tables 1-4 from Silencing of <i>CD24</i> Enhances the PRIMA-1–Induced Restoration of Mutant p53 in Prostate Cancer Cells Open
Figure S1: (Overexpression of CD24 mRNA in human PCa tissue based on analysis of three datasets); Figure S2: (Nuclear CD24 and p53 staining in human PCa cases); Figure S3: (The sequence-specific DNA binding sites of p53 in its target genes…
View article: Supplementary Figures 1-4 and Tables 1-4 from Silencing of <i>CD24</i> Enhances the PRIMA-1–Induced Restoration of Mutant p53 in Prostate Cancer Cells
Supplementary Figures 1-4 and Tables 1-4 from Silencing of <i>CD24</i> Enhances the PRIMA-1–Induced Restoration of Mutant p53 in Prostate Cancer Cells Open
Figure S1: (Overexpression of CD24 mRNA in human PCa tissue based on analysis of three datasets); Figure S2: (Nuclear CD24 and p53 staining in human PCa cases); Figure S3: (The sequence-specific DNA binding sites of p53 in its target genes…
View article: 204 IL-4 as a negative regulator of pathogenic extrafollicular DN2 B cells in SLE
204 IL-4 as a negative regulator of pathogenic extrafollicular DN2 B cells in SLE Open
Background Pathogenic extrafollicular double negative 2 (DN2) B cells in SLE have a phenotype of IgD−CD27−Tbet+CD11c+, and are the precursor of ribonuclear protein (RNP) autoantibody producing B cells. This trajectory of development is pro…
View article: Effect of Clostridium butyricum Supplementation on in vitro Rumen Fermentation and Microbiota With High Grain Substrate Varying With Media pH Levels
Effect of Clostridium butyricum Supplementation on in vitro Rumen Fermentation and Microbiota With High Grain Substrate Varying With Media pH Levels Open
Clostridium butyricum ( C. butyricum ) can survive at low pH, and it has been widely used as an alternative to antibiotics for the improvement of feed efficiency and animal health in monogastrics. A recent study suggested that the improved…
View article: Characterizing the Microbial Consortium L1 Capable of Efficiently Degrading Chlorimuron-Ethyl via Metagenome Combining 16S rDNA Sequencing
Characterizing the Microbial Consortium L1 Capable of Efficiently Degrading Chlorimuron-Ethyl via Metagenome Combining 16S rDNA Sequencing Open
Excessive application of the herbicide chlorimuron-ethyl (CE) severely harms subsequent crops and poses severe risks to environmental health. Therefore, methods for efficiently decreasing and eliminating CE residues are urgently needed. Mi…
View article: THE CONTRIBUTION OF LAND USE AND LAND COVER ON CARBON STORAGE IN THE NORTH TIBET PLATEAU, CHINA
THE CONTRIBUTION OF LAND USE AND LAND COVER ON CARBON STORAGE IN THE NORTH TIBET PLATEAU, CHINA Open
It’s important for understanding the impact of land use/ land cover (LULC) on carbon storage to optimize land use and ecosystem service payment scheme. Integrated the InVEST model with statistical analysis, carbon storage change in the Nor…
View article: Research on Fuzzy Adaptive Control Algorithm with Extended Dimension for Disturbance Torque
Research on Fuzzy Adaptive Control Algorithm with Extended Dimension for Disturbance Torque Open
In order to solve the problem that friction, wire-wound, wind resistance and other disturbing moments seriously affect the stability tracking precision during the task of the photoelectric pod system, the fuzzy adaptive control algorithm w…
View article: Extended Kalman Predictive Filter and Its Application in Theodolite System
Extended Kalman Predictive Filter and Its Application in Theodolite System Open
Tracking accuracy and pointing accuracy are the core indicators of photoelectric theodolite, and the speed stationarity in the process of tracking and pointing determines the quality of target image acquisition, affects the parameters acqu…
View article: Allergic fungal sinusitis caused by Schizophyllum commune
Allergic fungal sinusitis caused by Schizophyllum commune Open
A case of allergic fungal sinusitis (AFS) due to Schizophyllum commune was reported. The pathogen was identified using molecular bioanalysis. The patient underwent the functional endoscopic sinus surgery followed by the radical maxillary s…