Objective:To investigate whether paclitaxel (PTX) can induce immunogenic cell death (ICD) in vascular smooth muscle cells (VSMCs), and explore the new molecular mechanism of PTX-coated balloon angioplasty in intracranial atherosclerotic stenosis.Methods:(1) Cell culture and identification: VSMCs were induced into synthetic vascular smooth muscle cells (sVSMCs); the mRNA and protein expressions of smooth muscle protein 22-α (SM22-α) and α-smooth muscle actin (α-SMA) in VSMCsS and sVSMCs were detected by real-time fluorescent quantitative reverse transcriptase-polymerase chain reaction (qRT-PCR) and Western blotting, respectively. Human acute monocytic leukemia cell line THP-1 was induced into dendritic cells (DCs); the CD86 and CD83 expressions in THP-1 and DCs were detected by flow cytometry. (2) Cell viability detection: cell counting kit-8 (CCK-8) assay was used to detect the cell viability of sVSMCs after 0, 0.01, 0.05, 0.5, 5, 10, 50, and 100 μmol/L PTX or under 0, 50, 100, 200, 400, and 600 mmHg (1 mmHg=0.133 kPa) pressures. (3) ICD marker detection: sVSMCs were collected and divided into blank-control group, dimethyl sulfoxide (DMSO) group and PTX group (cultured with 3.2 μmol/L PTX) at normal state and pressure procedure (188 mmHg), respectively; calreticulin (CRT) expression was detected by immunofluorescent staining; adenosine triphosphate (ATP) expression was detected by luciferase assay, and high mobility group protein B1 (HMGB1) expression was detected by enzyme-linked immunosorbent assay (ELISA). (4) ICD-related immune activation assay detection: sVSMCs and DCs were collected and divided into DCs group, PTX+DCs group (cultured with 3.2 μmol/L PTX), DCs+sVSMCs group, and PTX+DCs+sVSMCs group (cultured with 3.2 μmol/L PTX); CD86 and CD83 expressions were detected by flow cytometry; interleukin (IL)-2, IL-10 and interferon-γ (IFN-γ) levels were detected by ELISA. The sVSMCs, DCs and CD8 +T cells were collected and divided into sVSMCs group, sVSMCs+DCs group, sVSMCs+CD8 +T cell group, sVSMCs+DCs+CD8 +T cell group, PTX+sVSMCs group (cultured with 3.2 μmol/L PTX), and PTX+sVSMCs+DCs+CD8 +T cell group (cultured with 3.2 μmol/L PTX); proliferation of these cells was detected by cell clone formation assay. Results:(1) The SM22-α and α-SMA mRNA and protein expressions in the sVSMCs group were significantly lower than those in the VSMCs group ( P<0.05); rate of double-positive CD83 and CD86 in the DCs group was significantly higher than that in the THP-1 group ( P<0.05). (2) The sVSMCs viability decreased in a concentration-dependent manner after PTX treatment at concentrations of 0, 0.01, 0.05, 0.5, 5, 10, 50, and 100 μmol/L, respectively, with significant differences ( P<0.05); half maximal inhibitory concentration (IC 50) of PTX on sVSMCs was 3.2 μmol/L; no significant difference in sVSMCs viability after 3.2 μmol/L PTX treatment was noted under 0, 50, 100, 200, 400, and 600 mmHg pressures ( P>0.05). (3) Under normal state and pressure procedure, CRT fluorescent intensity of sVSMCs in the PTX group (42.00±3.50, 24.19±2.41) was significantly higher than that in the blank-control group (8.60±1.8, 8.42±1.7) and DMSO group (10.23±1.47, 9.71±1.01), ATP luminescence intensity (17 399.33±2 035.58, 17 445.67±2 449.34) was significantly higher than that in the blank-control group (9 021.33±726.84, 10 271.33±2 194.22) and DMSO group (11 977.33±960.91, 11 683.33±419.50), and HMGB1 concentration ([3 258.31±502.08] pg/mL, [3 265.27±246.06] pg/mL) was significantly higher than that in the blank-control group ([1 156.48±184.96] pg/mL, [1 205.20±196.36] pg/mL) and DMSO group ([1 309.59±75.03] pg/mL, [1 265.51±14.52] pg/mL, P<0.05). (4) The PTX+DCs+sVSMCs group had significantly higher CD83, CD86, IFN-γ and IL-2 expressions and lower IL-10 expression than the DCs group, PTX+DCs group, and DCs+sVSMCs group ( P<0.05); the PTX+sVSMCs group and PTX+sVSMCs+DCs+CD8 +T cell group had significantly lower clone formation rate compared with the sVSMCs group, sVSMCs+DCs group, sVSMCs+CD8 +T cell group, and sVSMCs+DCs+CD8 +T cell group ( P<0.05). Conclusion:PTX can promote ICD in VSMCs by promoting DCs activation and enhancing CD8 +T cell toxicity.

Objective:To investigate the mechanism of mitochondrial DNA (mtDNA)-reactive oxygen species (ROS)-dynamin-related protein 1 (Drp1) axis in regulating phenotypic transformation of vascular smooth muscle cells (VSMCs).Methods:(1) VSMCs were divided into a control group, a synthetic VSMCs group, and a Drp1 siRNA+synthetic VSMCs group; cells in the Drp1 siRNA+synthetic VSMCs group were transfected with 50 nmol/L Drp1 siRNA for 48 h; cells in the latter two groups were treated with 20 ng/mL platelet-derived growth factor (PDGF)-BB, while cells in the control group were treated with an equal volume of solvent. After another 24 h of culture, Drp1 expression in VSMCs, and mitochondrial Drp1 and mitofusin 2 (Mfn2) expressions were detected by Western blotting, and changes in mitochondrial morphology were detected by mitochondrial fluorescent staining. (2) VSMCs were divided into a control group, a synthetic VSMCs group, and a mitochondrial fission inhibitor 1 (Mdivi-1)+synthetic VSMCs group; cells in the Mdivi-1+synthetic VSMCs group were pretreated with 50 μmol/L Mdivi-1 for 2 h; and cells in the latter two groups were treated with 20 ng/mL PDGF-BB, while cells in the control group were treated with an equal volume of solvent. After 24 hours of continued culture, expressions of α-smooth muscle actin (α-SMA), smooth muscle protein 22-α (SM22-α), proliferating cell nuclear antigen (PCNA), and Cyclin D1 were detected by Western blotting; invasion and migration abilities of VSMCs were detected by Transwell assay and scratch wound healing assay, respectively. (3) VSMCs were divided into a control group, a synthetic VSMCs group, and a N-acetylcysteine (NAC)+synthetic VSMCs group; cells in the NAC+synthetic VSMCs group were pretreated with 5 mmol/L NAC for 1 h; cells in the latter two groups were treated with 20 ng/mL PDGF-BB, while cells in the control group were treated with an equal volume of solvent. After 24 h of continued culture, expressions of Drp1, phosphorylated (p)-Drp1, α-SMA, SM22-α, PCNA, and Cyclin D1 were detected by Western blotting; changes in mitochondrial morphology were detected by mitochondrial fluorescent staining; intracellular ROS level was detected by 2', 7' -dichlorodihydrofluorescein diacetate (DCFH-DA) fluorescent probe; cell invasion and migration abilities were detected by Transwell assay and scratch wound healing assay, respectively. (4) VSMCs were divided into a control group, a synthetic VSMCs group, and a 5-Aza-2'-deoxycytidine (5-Aza-dC)+synthetic VSMCs group; cells in the 5-Aza-dC+synthetic VSMCs group were pretreated with 2 μmol/L 5-Aza-dC for 1 h; and then, cells in the latter two groups were treated with 20 ng/mL PDGF-BB, while cells in the control group were treated with an equal volume of solvent. After 24 h of continued culture, agarose gel electrophoresis was used to analyze the methylation degree in the mitochondrial D-loop region; intracellular ROS level was detected using DCFH-DA fluorescent probe; expressions of mitochondrial DNMT1, α-SMA, SM22-α, PCNA, and Cyclin D1 were detected by Western blotting; invasion and migration abilities were detected by Transwell assay and scratch wound healing assay, respectively.Results:(1) Compared with the control group and synthetic VSMCs group, the Drp1 siRNA+synthetic VSMCs group had significantly decreased Drp1 protein expression ( P<0.05). Compared with the control group, the synthetic VSMCs group had significantly increased Drp1 protein expression and decreased Mfn2 protein expression in the mitochondria ( P<0.05); compared with the synthetic VSMCs group, the Drp1 siRNA+synthetic VSMCs group had statistically decreased Drp1 protein expression and increased Mfn2 protein expression in the mitochondria ( P<0.05). Results of mitochondrial fluorescent staining showed that mitochondria in the control group were with filamentous structure, while mitochondrial fission in the synthetic VSMCs group was enhanced, and morphology of mitochondria in the Drp1 siRNA+synthetic VSMCs group tended to be continuous and complete. (2) Compared with the control group, the synthetic VSMCs group had statistically decreased α-SMA and SM22-α protein expressions and increased PCNA and Cyclin D1 protein expressions ( P<0.05). Compared with the synthetic VSMCs group, the Mdivi-1+synthetic VSMCs group had significantly increased α-SMA and SM22-α protein expressions and decreased PCNA and Cyclin D1 protein expressions ( P<0.05). Results of Transwell and scratch wound healing assays showed that compared with the control group, the synthetic VSMCs group had larger number of migrating cells and faster cell scratch healing; compared with the synthetic VSMCs group, the Mdivi-1+synthetic VSMCs group had smaller number of migrating cells and slower cell scratch healing. (3) Compared with the control group (1.10±0.02), the synthetic VSMCs group (1.53±0.02) had significantly increased p-Drp1 protein expression ( P<0.05). Compared with the synthetic VSMCs group, the NAC+synthetic VSMCs group (0.90±0.02) had statistically decreased p-Drp1 protein expression ( P<0.05). Results of mitochondrial fluorescent staining showed that mitochondria in cells of the control group were in a filamentous structure, while mitochondrial fission in cells of the synthetic VSMCs group was enhanced, and morphology of mitochondria in the NAC+synthetic VSMCs group tended to be continuous and complete. Results of DCFH-DA fluorescent probe showed that ROS level in the synthetic VSMCs group was higher than that in the control group, and ROS level in the NAC+synthetic VSMCs group was lower than that in the synthetic VSMCs group. Compared with the control group, the synthetic VSMCs group had significantly decreased α-SMA and SM22-α protein expressions and increased PCNA and Cyclin D1 protein expressions ( P<0.05). Compared with the synthetic VSMCs group, the NAC+synthetic VSMCs group had significantly increased α-SMA and SM22-α protein expressions and decreased PCNA and Cyclin D1 protein expressions ( P<0.05). Results of Transwell and scratch wound healing assays showed that compared with the control group, the synthetic VSMCs group had larger number of migrating cells and faster cell scratch healing; compared with the synthetic VSMCs group, the NAC+synthetic VSMCs group had smaller number of migrating cells and slower cell scratch healing. (4) Results of agarose gel electrophoresis showed that compared with the control group, the synthetic VSMCs group had significantly increased methylation rate in the mitochondrial D-loop region ( P<0.05); compared with the synthetic VSMCs group, the 5-Aza-dC+synthetic VSMCs group had statistically decreased methylation rate in the mitochondrial D-loop region ( P<0.05). Compared with the control group, the synthetic VSMCs group had statistically increased mitochondrial DNMT1 protein expression (1.03±0.03 vs. 0.55±0.03, P<0.05); and compared with the synthetic VSMCs group, the the 5-Aza-dC+synthetic VSMCs group (0.62±0.03) had significantly decreased mitochondrial DNMT1 protein expression ( P<0.05). Results of DCFH-DA fluorescent probe showed that ROS level in the synthetic VSMCs group was higher than that in the control group; ROS level in the 5-Aza-dC+synthetic VSMCs group was lower than that in the synthetic VSMCs group. Compared with the control group, the synthetic VSMCs group had significantly decreased α-SMA and SM22-α protein expressions and increased PCNA and Cyclin D1 protein expressions ( P<0.05). Compared with the synthetic VSMCs group, the 5-Aza-dC+synthetic VSMCs group had significantly increased α-SMA and SM22-α protein expressions and decreased PCNA and Cyclin D1 protein expressions ( P<0.05). Results of Transwell and scratch wound healing assays showed that compared with the control group, the synthetic VSMCs group had larger number of migrating cells and faster scratch healing. Compared with the synthetic VSMCs group, the 5-Aza-dC+synthetic VSMCs group had smaller number of migrating cells and slower scratch healing. Conclusion:The mtDNA-ROS-Drp1 axis may regulate the phenotypic transformation of VSMCs by modulating mitochondrial epigenetic modifications.

Objective:To explore the construction of an evaluation model for aortic root anatomy and calcium burden in patients with bicuspid aortic valve (BAV) stenosis before transcatheter aortic valve replacement (TAVR) based on deep learning (DL) algorithms.Methods:A retrospective collection of 362 BAV stenosis patients who underwent TAVR from September 2023 to May 2024 was performed. All patients underwent cardiac CT angiography. The patients were divided into training group ( n=104), internal validation group ( n=206), and external validation group ( n=52). A DL model was trained on the training dataset to assess aortic root anatomy and calcification burden. The evaluation included the segmentation accuracy of the algorithm, the measurement performance of key anatomical structures (i.e., valve leaflets and type-1 and type-2 fusion raphe), and calcification burden, as well as the measurement efficiency. Overall segmentation performance was assessed using the average Dice coefficient (ADC). The fine-scale segmentation quality was validated by the 95th-percentile Hausdorff distance (HD-95) and the average symmetric surface distance (ASSD). The consistency of the measurement results was assessed using the Pearson correlation coefficient and the intraclass correlation coefficient ( ICC) with a two-way mixed model for absolute agreement. In addition, the total time and total mouse movement distance required for manual assessment versus the DL model on the validation datasets were recorded and compared. Results:The algorithm demonstrated excellent segmentation performance on aortic root anatomical targets, achieving outstanding consistency within both internal and external validation datasets (0.955

Objective:To explore the construction of an evaluation model for aortic root anatomy and calcium burden in patients with bicuspid aortic valve (BAV) stenosis before transcatheter aortic valve replacement (TAVR) based on deep learning (DL) algorithms.Methods:A retrospective collection of 362 BAV stenosis patients who underwent TAVR from September 2023 to May 2024 was performed. All patients underwent cardiac CT angiography. The patients were divided into training group ( n=104), internal validation group ( n=206), and external validation group ( n=52). A DL model was trained on the training dataset to assess aortic root anatomy and calcification burden. The evaluation included the segmentation accuracy of the algorithm, the measurement performance of key anatomical structures (i.e., valve leaflets and type-1 and type-2 fusion raphe), and calcification burden, as well as the measurement efficiency. Overall segmentation performance was assessed using the average Dice coefficient (ADC). The fine-scale segmentation quality was validated by the 95th-percentile Hausdorff distance (HD-95) and the average symmetric surface distance (ASSD). The consistency of the measurement results was assessed using the Pearson correlation coefficient and the intraclass correlation coefficient ( ICC) with a two-way mixed model for absolute agreement. In addition, the total time and total mouse movement distance required for manual assessment versus the DL model on the validation datasets were recorded and compared. Results:The algorithm demonstrated excellent segmentation performance on aortic root anatomical targets, achieving outstanding consistency within both internal and external validation datasets (0.955

Objective:To investigate whether paclitaxel (PTX) can induce immunogenic cell death (ICD) in vascular smooth muscle cells (VSMCs), and explore the new molecular mechanism of PTX-coated balloon angioplasty in intracranial atherosclerotic stenosis.Methods:(1) Cell culture and identification: VSMCs were induced into synthetic vascular smooth muscle cells (sVSMCs); the mRNA and protein expressions of smooth muscle protein 22-α (SM22-α) and α-smooth muscle actin (α-SMA) in VSMCsS and sVSMCs were detected by real-time fluorescent quantitative reverse transcriptase-polymerase chain reaction (qRT-PCR) and Western blotting, respectively. Human acute monocytic leukemia cell line THP-1 was induced into dendritic cells (DCs); the CD86 and CD83 expressions in THP-1 and DCs were detected by flow cytometry. (2) Cell viability detection: cell counting kit-8 (CCK-8) assay was used to detect the cell viability of sVSMCs after 0, 0.01, 0.05, 0.5, 5, 10, 50, and 100 μmol/L PTX or under 0, 50, 100, 200, 400, and 600 mmHg (1 mmHg=0.133 kPa) pressures. (3) ICD marker detection: sVSMCs were collected and divided into blank-control group, dimethyl sulfoxide (DMSO) group and PTX group (cultured with 3.2 μmol/L PTX) at normal state and pressure procedure (188 mmHg), respectively; calreticulin (CRT) expression was detected by immunofluorescent staining; adenosine triphosphate (ATP) expression was detected by luciferase assay, and high mobility group protein B1 (HMGB1) expression was detected by enzyme-linked immunosorbent assay (ELISA). (4) ICD-related immune activation assay detection: sVSMCs and DCs were collected and divided into DCs group, PTX+DCs group (cultured with 3.2 μmol/L PTX), DCs+sVSMCs group, and PTX+DCs+sVSMCs group (cultured with 3.2 μmol/L PTX); CD86 and CD83 expressions were detected by flow cytometry; interleukin (IL)-2, IL-10 and interferon-γ (IFN-γ) levels were detected by ELISA. The sVSMCs, DCs and CD8 +T cells were collected and divided into sVSMCs group, sVSMCs+DCs group, sVSMCs+CD8 +T cell group, sVSMCs+DCs+CD8 +T cell group, PTX+sVSMCs group (cultured with 3.2 μmol/L PTX), and PTX+sVSMCs+DCs+CD8 +T cell group (cultured with 3.2 μmol/L PTX); proliferation of these cells was detected by cell clone formation assay. Results:(1) The SM22-α and α-SMA mRNA and protein expressions in the sVSMCs group were significantly lower than those in the VSMCs group ( P<0.05); rate of double-positive CD83 and CD86 in the DCs group was significantly higher than that in the THP-1 group ( P<0.05). (2) The sVSMCs viability decreased in a concentration-dependent manner after PTX treatment at concentrations of 0, 0.01, 0.05, 0.5, 5, 10, 50, and 100 μmol/L, respectively, with significant differences ( P<0.05); half maximal inhibitory concentration (IC 50) of PTX on sVSMCs was 3.2 μmol/L; no significant difference in sVSMCs viability after 3.2 μmol/L PTX treatment was noted under 0, 50, 100, 200, 400, and 600 mmHg pressures ( P>0.05). (3) Under normal state and pressure procedure, CRT fluorescent intensity of sVSMCs in the PTX group (42.00±3.50, 24.19±2.41) was significantly higher than that in the blank-control group (8.60±1.8, 8.42±1.7) and DMSO group (10.23±1.47, 9.71±1.01), ATP luminescence intensity (17 399.33±2 035.58, 17 445.67±2 449.34) was significantly higher than that in the blank-control group (9 021.33±726.84, 10 271.33±2 194.22) and DMSO group (11 977.33±960.91, 11 683.33±419.50), and HMGB1 concentration ([3 258.31±502.08] pg/mL, [3 265.27±246.06] pg/mL) was significantly higher than that in the blank-control group ([1 156.48±184.96] pg/mL, [1 205.20±196.36] pg/mL) and DMSO group ([1 309.59±75.03] pg/mL, [1 265.51±14.52] pg/mL, P<0.05). (4) The PTX+DCs+sVSMCs group had significantly higher CD83, CD86, IFN-γ and IL-2 expressions and lower IL-10 expression than the DCs group, PTX+DCs group, and DCs+sVSMCs group ( P<0.05); the PTX+sVSMCs group and PTX+sVSMCs+DCs+CD8 +T cell group had significantly lower clone formation rate compared with the sVSMCs group, sVSMCs+DCs group, sVSMCs+CD8 +T cell group, and sVSMCs+DCs+CD8 +T cell group ( P<0.05). Conclusion:PTX can promote ICD in VSMCs by promoting DCs activation and enhancing CD8 +T cell toxicity.

Objective:To investigate the mechanism of mitochondrial DNA (mtDNA)-reactive oxygen species (ROS)-dynamin-related protein 1 (Drp1) axis in regulating phenotypic transformation of vascular smooth muscle cells (VSMCs).Methods:(1) VSMCs were divided into a control group, a synthetic VSMCs group, and a Drp1 siRNA+synthetic VSMCs group; cells in the Drp1 siRNA+synthetic VSMCs group were transfected with 50 nmol/L Drp1 siRNA for 48 h; cells in the latter two groups were treated with 20 ng/mL platelet-derived growth factor (PDGF)-BB, while cells in the control group were treated with an equal volume of solvent. After another 24 h of culture, Drp1 expression in VSMCs, and mitochondrial Drp1 and mitofusin 2 (Mfn2) expressions were detected by Western blotting, and changes in mitochondrial morphology were detected by mitochondrial fluorescent staining. (2) VSMCs were divided into a control group, a synthetic VSMCs group, and a mitochondrial fission inhibitor 1 (Mdivi-1)+synthetic VSMCs group; cells in the Mdivi-1+synthetic VSMCs group were pretreated with 50 μmol/L Mdivi-1 for 2 h; and cells in the latter two groups were treated with 20 ng/mL PDGF-BB, while cells in the control group were treated with an equal volume of solvent. After 24 hours of continued culture, expressions of α-smooth muscle actin (α-SMA), smooth muscle protein 22-α (SM22-α), proliferating cell nuclear antigen (PCNA), and Cyclin D1 were detected by Western blotting; invasion and migration abilities of VSMCs were detected by Transwell assay and scratch wound healing assay, respectively. (3) VSMCs were divided into a control group, a synthetic VSMCs group, and a N-acetylcysteine (NAC)+synthetic VSMCs group; cells in the NAC+synthetic VSMCs group were pretreated with 5 mmol/L NAC for 1 h; cells in the latter two groups were treated with 20 ng/mL PDGF-BB, while cells in the control group were treated with an equal volume of solvent. After 24 h of continued culture, expressions of Drp1, phosphorylated (p)-Drp1, α-SMA, SM22-α, PCNA, and Cyclin D1 were detected by Western blotting; changes in mitochondrial morphology were detected by mitochondrial fluorescent staining; intracellular ROS level was detected by 2', 7' -dichlorodihydrofluorescein diacetate (DCFH-DA) fluorescent probe; cell invasion and migration abilities were detected by Transwell assay and scratch wound healing assay, respectively. (4) VSMCs were divided into a control group, a synthetic VSMCs group, and a 5-Aza-2'-deoxycytidine (5-Aza-dC)+synthetic VSMCs group; cells in the 5-Aza-dC+synthetic VSMCs group were pretreated with 2 μmol/L 5-Aza-dC for 1 h; and then, cells in the latter two groups were treated with 20 ng/mL PDGF-BB, while cells in the control group were treated with an equal volume of solvent. After 24 h of continued culture, agarose gel electrophoresis was used to analyze the methylation degree in the mitochondrial D-loop region; intracellular ROS level was detected using DCFH-DA fluorescent probe; expressions of mitochondrial DNMT1, α-SMA, SM22-α, PCNA, and Cyclin D1 were detected by Western blotting; invasion and migration abilities were detected by Transwell assay and scratch wound healing assay, respectively.Results:(1) Compared with the control group and synthetic VSMCs group, the Drp1 siRNA+synthetic VSMCs group had significantly decreased Drp1 protein expression ( P<0.05). Compared with the control group, the synthetic VSMCs group had significantly increased Drp1 protein expression and decreased Mfn2 protein expression in the mitochondria ( P<0.05); compared with the synthetic VSMCs group, the Drp1 siRNA+synthetic VSMCs group had statistically decreased Drp1 protein expression and increased Mfn2 protein expression in the mitochondria ( P<0.05). Results of mitochondrial fluorescent staining showed that mitochondria in the control group were with filamentous structure, while mitochondrial fission in the synthetic VSMCs group was enhanced, and morphology of mitochondria in the Drp1 siRNA+synthetic VSMCs group tended to be continuous and complete. (2) Compared with the control group, the synthetic VSMCs group had statistically decreased α-SMA and SM22-α protein expressions and increased PCNA and Cyclin D1 protein expressions ( P<0.05). Compared with the synthetic VSMCs group, the Mdivi-1+synthetic VSMCs group had significantly increased α-SMA and SM22-α protein expressions and decreased PCNA and Cyclin D1 protein expressions ( P<0.05). Results of Transwell and scratch wound healing assays showed that compared with the control group, the synthetic VSMCs group had larger number of migrating cells and faster cell scratch healing; compared with the synthetic VSMCs group, the Mdivi-1+synthetic VSMCs group had smaller number of migrating cells and slower cell scratch healing. (3) Compared with the control group (1.10±0.02), the synthetic VSMCs group (1.53±0.02) had significantly increased p-Drp1 protein expression ( P<0.05). Compared with the synthetic VSMCs group, the NAC+synthetic VSMCs group (0.90±0.02) had statistically decreased p-Drp1 protein expression ( P<0.05). Results of mitochondrial fluorescent staining showed that mitochondria in cells of the control group were in a filamentous structure, while mitochondrial fission in cells of the synthetic VSMCs group was enhanced, and morphology of mitochondria in the NAC+synthetic VSMCs group tended to be continuous and complete. Results of DCFH-DA fluorescent probe showed that ROS level in the synthetic VSMCs group was higher than that in the control group, and ROS level in the NAC+synthetic VSMCs group was lower than that in the synthetic VSMCs group. Compared with the control group, the synthetic VSMCs group had significantly decreased α-SMA and SM22-α protein expressions and increased PCNA and Cyclin D1 protein expressions ( P<0.05). Compared with the synthetic VSMCs group, the NAC+synthetic VSMCs group had significantly increased α-SMA and SM22-α protein expressions and decreased PCNA and Cyclin D1 protein expressions ( P<0.05). Results of Transwell and scratch wound healing assays showed that compared with the control group, the synthetic VSMCs group had larger number of migrating cells and faster cell scratch healing; compared with the synthetic VSMCs group, the NAC+synthetic VSMCs group had smaller number of migrating cells and slower cell scratch healing. (4) Results of agarose gel electrophoresis showed that compared with the control group, the synthetic VSMCs group had significantly increased methylation rate in the mitochondrial D-loop region ( P<0.05); compared with the synthetic VSMCs group, the 5-Aza-dC+synthetic VSMCs group had statistically decreased methylation rate in the mitochondrial D-loop region ( P<0.05). Compared with the control group, the synthetic VSMCs group had statistically increased mitochondrial DNMT1 protein expression (1.03±0.03 vs. 0.55±0.03, P<0.05); and compared with the synthetic VSMCs group, the the 5-Aza-dC+synthetic VSMCs group (0.62±0.03) had significantly decreased mitochondrial DNMT1 protein expression ( P<0.05). Results of DCFH-DA fluorescent probe showed that ROS level in the synthetic VSMCs group was higher than that in the control group; ROS level in the 5-Aza-dC+synthetic VSMCs group was lower than that in the synthetic VSMCs group. Compared with the control group, the synthetic VSMCs group had significantly decreased α-SMA and SM22-α protein expressions and increased PCNA and Cyclin D1 protein expressions ( P<0.05). Compared with the synthetic VSMCs group, the 5-Aza-dC+synthetic VSMCs group had significantly increased α-SMA and SM22-α protein expressions and decreased PCNA and Cyclin D1 protein expressions ( P<0.05). Results of Transwell and scratch wound healing assays showed that compared with the control group, the synthetic VSMCs group had larger number of migrating cells and faster scratch healing. Compared with the synthetic VSMCs group, the 5-Aza-dC+synthetic VSMCs group had smaller number of migrating cells and slower scratch healing. Conclusion:The mtDNA-ROS-Drp1 axis may regulate the phenotypic transformation of VSMCs by modulating mitochondrial epigenetic modifications.

Here, we report a previously unrecognized syndromic neurodevelopmental disorder associated with biallelic loss-of-function variants in the RBM42 gene. The patient is a 2-year-old female with severe central nervous system (CNS) abnormalities, hypotonia, hearing loss, congenital heart defects, and dysmorphic facial features. Familial whole-exome sequencing (WES) reveals that the patient has two compound heterozygous variants, c.304C>T (p.R102*) and c.1312G>A (p.A438T), in the RBM42 gene which encodes an integral component of splicing complex in the RNA-binding motif protein family. The p.A438T variant is in the RRM domain which impairs RBM42 protein stability in vivo. Additionally, p.A438T disrupts the interaction of RBM42 with hnRNP K, which is the causative gene for Au-Kline syndrome with overlapping disease characteristics seen in the index patient. The human R102* or A438T mutant protein failed to fully rescue the growth defects of RBM42 ortholog knockout ΔFgRbp1 in Fusarium while it was rescued by the wild-type (WT) human RBM42. A mouse model carrying Rbm42 compound heterozygous variants, c.280C>T (p.Q94*) and c.1306_1308delinsACA (p.A436T), demonstrated gross fetal developmental defects and most of the double mutant animals died by E13.5. RNA-seq data confirmed that Rbm42 was involved in neurological and myocardial functions with an essential role in alternative splicing (AS). Overall, we present clinical, genetic, and functional data to demonstrate that defects in RBM42 constitute the underlying etiology of a new neurodevelopmental disease which links the dysregulation of global AS to abnormal embryonic development.
Female ; Animals ; Mice ; Humans ; Child, Preschool ; Intellectual Disability/genetics* ; Heart Defects, Congenital/genetics* ; Facies ; Cleft Palate ; Muscle Hypotonia

Shengmai formula,composed of Ginseng Radix et Rhizoma,Ophiopogon Radix and Schisandrae Chinensis Fructus,is a classic and famous formula.It is a representative formula for"supplementing qi,nourishing yin,and generating fluid"in Traditional Chinese Medicine theory.To date,a wide range of Shengmai formulae have been developed according to different medical applications,but the quality evaluation standards are at a relatively low level,and most of them only specify the individual components of a single herb,making it difficult to ensure clinical efficacy and safety.At the same time,the physical and chemical identification methods of Shengmai formula have been constantly updated,allowing for greater progress in research on its main chemical components such as saponins,lignans and flavonoids.However,there is little systematic summarization of the chemical components and analytical methods.Based on the existing references,we systematically summarized ginsenosides,ophiopogonins,schisandra lignans,homoisoflavonoids and some other compounds in this paper,as well as the quality standards of Shengmai formulae and their analytical methods in order to aid clinical research and formulation manufacture.

Objective:To analyze the research hotspots and trends in the field of pressure injury support surfaces both domestically and abroad and to provide references for future studies in this domain.Methods:Relevant literature on pressure injury support surfaces indexed in the Web of Science Core Collection, CNKI, Wanfang, and VIP database were retrieved, with the search spanning from January 1, 2010, to February 28, 2023. CiteSpace was utilized to perform a visualization analysis of the amassed data.Results:A total of 307 Chinese articles and 434 English articles were included in the analysis. The United States emerged as the country with the highest number of publications. The General Hospital of Eastern Military Command topped the list in China in terms of the number of publications. Chinese Journal of Modern Nursing and Journal of Tissue Viability were the journals with the highest publication frequencies in China and abroad, respectively. Jiang Qixia was the author with the highest number of publications in China, while Gefen secured this position internationally. The Chinese literature formed 12 clusters and the English literature formed 17, culminating in the identification of 8 meaningful categories (population, location, research type, risk factors, static support surfaces, dynamic support surfaces, intelligent monitoring, and effectiveness evaluation), among which intelligent monitoring was seen as a future research trend. Conclusions:Pressure injury support surfaces have been a research hotspot in recent years both domestically and internationally. It is recommended to promote the development of domestic research on pressure injury preventive care through strategies such as expanding the range of research populations, developing intelligent support surface devices conducive to promotion in collaboration with computer and artificial intelligence disciplines, and carrying out large-scale high-quality original research and corresponding quality improvement projects.

Hypoxia is a common feature of solid tumors. As transcription factors, hypoxia-inducible factors (HIFs) are the master regulators of the hypoxic microenvironment; their target genes function in tumorigenesis and tumor development. Intriguingly, both yes-associated protein (YAP) and its paralog transcriptional coactivator with a PDZ-binding motif (TAZ) play fundamental roles in the malignant progression of hypoxic tumors. As downstream effectors of the mammalian Hippo pathway, YAP and/or TAZ (YAP/TAZ) are phosphorylated and sequestered in the cytoplasm by the large tumor suppressor kinase 1/2 (LATS1/2)-MOB kinase activator 1 (MOB1) complex, which restricts the transcriptional activity of YAP/TAZ. However, dephosphorylated YAP/TAZ have the ability to translocate to the nucleus where they induce transcription of target genes, most of which are closely related to cancer. Herein we review the tumor-related signaling crosstalk between YAP/TAZ and hypoxia, describe current agents and therapeutic strategies targeting the hypoxia-YAP/TAZ axis, and highlight questions that might have a potential impact in the future.