1.Chinese expert consensus on integrated case management by a multidisciplinary team in CAR-T cell therapy for lymphoma.
Sanfang TU ; Ping LI ; Heng MEI ; Yang LIU ; Yongxian HU ; Peng LIU ; Dehui ZOU ; Ting NIU ; Kailin XU ; Li WANG ; Jianmin YANG ; Mingfeng ZHAO ; Xiaojun HUANG ; Jianxiang WANG ; Yu HU ; Weili ZHAO ; Depei WU ; Jun MA ; Wenbin QIAN ; Weidong HAN ; Yuhua LI ; Aibin LIANG
Chinese Medical Journal 2025;138(16):1894-1896
2.Effect of avatrobopag on hematopoietic reconstitution after allogeneic hematopoietic stem cell transplantation
Jingjing ZHU ; Xiuli LIANG ; Li HAN ; Xuedong SHI ; Shuqi WANG ; Zhenyu LI ; Kailin XU ; Hai CHENG
Chinese Journal of Organ Transplantation 2025;46(5):365-374
Objective:To investigate the efficacy and safety of avatrombopag in promoting hematopoietic reconstitution after allogeneic hematopoietic stem cell transplantation (allo-HSCT).Method:A retrospective analysis was conducted on 60 recipients with hematological malignancies who underwent allo-HSCT at the Affiliated Hospital of Xuzhou Medical University from January 2022 to August 2023. Recipients with hepatic or renal insufficiency before conditioning, those who received other thrombopoietic agents after allo-HSCT, those with severe respiratory or circulatory system diseases, and those with a history of thromboembolic events were excluded. Among them, 30 recipients who received avatrombopag within 14 days post-transplantation were assigned to the avatrombopag group, while the remaining 30 recipients who did not receive any thrombopoietic agents served as the control group. Clinical characteristics, hematopoietic stem cell engraftment, bone marrow proliferation, transfusion requirements, transplant-related complications, and laboratory adverse events were compared between the two groups.Result:The median platelet engraftment time in the avatrombopag group was 13 days (range: 9~25 days), and the neutrophil engraftment time was 13 days (range: 11~21 days). In the control group, he platelet engraftment time was 15 days (range: 10~51 days), and neutrophil engraftment time was 14 days (range: 10~30 days). The difference in platelet engraftment time between the two groups was statistically significant ( P=0.039). Bone marrow analysis on day 28 post-transplant showed that the proportion of recipients with active bone marrow hyperplasia was 96.7% in the avatrombopag group and 73.3% in the control group ( P=0.030); the median number of megakaryocytes was 30 vs. 6, respectively ( P<0.001); and the proportion of mature platelet-producing megakaryocytes was 44% vs. 26.3% ( P<0.001). Regarding transfusion requirements, the median platelet transfusion volume within 28 days post-transplantation was 4.5 U (range: 2~16 U) in the avatrombopag group and 6.5 U (range: 3~32 U) in the control group ( P=0.007). The time to achieve platelet transfusion independence was 13 days (range: 8~25 days) in the avatrombopag group and 14 days (range: 10~36 days) in the control group ( P=0.026). The median red blood cell transfusion volume in both groups was 4 U, with no significant difference ( P=0.354). Medication adherence in the avatrombopag group was 100%. There were no statistically significant differences between the two groups in terms of incidence of post-transplant infections (70% vs. 83.3%), bleeding (50% vs. 60%), graft-versus-host disease (GVHD) (30% vs. 40%), or abnormal laboratory tests (86.7% vs. 90%) (all P>0.05). Conclusion:The use of avatrombopag after allo-HSCT in patients with hematologic malignancies can promote bone marrow hematopoiesis and platelet engraftment, reduce platelet transfusion volume, and shorten the duration of platelet transfusion dependence. Avatrombopag is well tolerated, and no serious adverse reactions were observed during treatment.
3.Effect of avatrobopag on hematopoietic reconstitution after allogeneic hematopoietic stem cell transplantation
Jingjing ZHU ; Xiuli LIANG ; Li HAN ; Xuedong SHI ; Shuqi WANG ; Zhenyu LI ; Kailin XU ; Hai CHENG
Chinese Journal of Organ Transplantation 2025;46(5):365-374
Objective:To investigate the efficacy and safety of avatrombopag in promoting hematopoietic reconstitution after allogeneic hematopoietic stem cell transplantation (allo-HSCT).Method:A retrospective analysis was conducted on 60 recipients with hematological malignancies who underwent allo-HSCT at the Affiliated Hospital of Xuzhou Medical University from January 2022 to August 2023. Recipients with hepatic or renal insufficiency before conditioning, those who received other thrombopoietic agents after allo-HSCT, those with severe respiratory or circulatory system diseases, and those with a history of thromboembolic events were excluded. Among them, 30 recipients who received avatrombopag within 14 days post-transplantation were assigned to the avatrombopag group, while the remaining 30 recipients who did not receive any thrombopoietic agents served as the control group. Clinical characteristics, hematopoietic stem cell engraftment, bone marrow proliferation, transfusion requirements, transplant-related complications, and laboratory adverse events were compared between the two groups.Result:The median platelet engraftment time in the avatrombopag group was 13 days (range: 9~25 days), and the neutrophil engraftment time was 13 days (range: 11~21 days). In the control group, he platelet engraftment time was 15 days (range: 10~51 days), and neutrophil engraftment time was 14 days (range: 10~30 days). The difference in platelet engraftment time between the two groups was statistically significant ( P=0.039). Bone marrow analysis on day 28 post-transplant showed that the proportion of recipients with active bone marrow hyperplasia was 96.7% in the avatrombopag group and 73.3% in the control group ( P=0.030); the median number of megakaryocytes was 30 vs. 6, respectively ( P<0.001); and the proportion of mature platelet-producing megakaryocytes was 44% vs. 26.3% ( P<0.001). Regarding transfusion requirements, the median platelet transfusion volume within 28 days post-transplantation was 4.5 U (range: 2~16 U) in the avatrombopag group and 6.5 U (range: 3~32 U) in the control group ( P=0.007). The time to achieve platelet transfusion independence was 13 days (range: 8~25 days) in the avatrombopag group and 14 days (range: 10~36 days) in the control group ( P=0.026). The median red blood cell transfusion volume in both groups was 4 U, with no significant difference ( P=0.354). Medication adherence in the avatrombopag group was 100%. There were no statistically significant differences between the two groups in terms of incidence of post-transplant infections (70% vs. 83.3%), bleeding (50% vs. 60%), graft-versus-host disease (GVHD) (30% vs. 40%), or abnormal laboratory tests (86.7% vs. 90%) (all P>0.05). Conclusion:The use of avatrombopag after allo-HSCT in patients with hematologic malignancies can promote bone marrow hematopoiesis and platelet engraftment, reduce platelet transfusion volume, and shorten the duration of platelet transfusion dependence. Avatrombopag is well tolerated, and no serious adverse reactions were observed during treatment.
4.Recommendations for the timing, dosage, and usage of corticosteroids during cytokine release syndrome (CRS) caused by chimeric antigen receptor (CAR)-T cell therapy for hematologic malignancies.
Sanfang TU ; Xiu LUO ; Heng MEI ; Yongxian HU ; Yang LIU ; Ping LI ; Dehui ZOU ; Ting NIU ; Kailin XU ; Xi ZHANG ; Lugui QIU ; Lei GAO ; Guangxun GAO ; Li ZHANG ; Yimei FENG ; Ying WANG ; Mingfeng ZHAO ; Jianqing MI ; Ming HOU ; Jianmin YANG ; He HUANG ; Jianxiang WANG ; Yu HU ; Weili ZHAO ; Depei WU ; Jun MA ; Yuhua LI ; Wenbin QIAN ; Xiaojun HUANG ; Weidong HAN ; Aibin LIANG
Chinese Medical Journal 2024;137(22):2681-2683
5.High-throughput screening identifies established drugs as SARS-CoV-2 PLpro inhibitors.
Yao ZHAO ; Xiaoyu DU ; Yinkai DUAN ; Xiaoyan PAN ; Yifang SUN ; Tian YOU ; Lin HAN ; Zhenming JIN ; Weijuan SHANG ; Jing YU ; Hangtian GUO ; Qianying LIU ; Yan WU ; Chao PENG ; Jun WANG ; Chenghao ZHU ; Xiuna YANG ; Kailin YANG ; Ying LEI ; Luke W GUDDAT ; Wenqing XU ; Gengfu XIAO ; Lei SUN ; Leike ZHANG ; Zihe RAO ; Haitao YANG
Protein & Cell 2021;12(11):877-888
A new coronavirus (SARS-CoV-2) has been identified as the etiologic agent for the COVID-19 outbreak. Currently, effective treatment options remain very limited for this disease; therefore, there is an urgent need to identify new anti-COVID-19 agents. In this study, we screened over 6,000 compounds that included approved drugs, drug candidates in clinical trials, and pharmacologically active compounds to identify leads that target the SARS-CoV-2 papain-like protease (PLpro). Together with main protease (M
Antiviral Agents/therapeutic use*
;
Binding Sites
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COVID-19/virology*
;
Coronavirus Papain-Like Proteases/metabolism*
;
Crystallography, X-Ray
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Drug Evaluation, Preclinical
;
Drug Repositioning
;
High-Throughput Screening Assays/methods*
;
Humans
;
Imidazoles/therapeutic use*
;
Inhibitory Concentration 50
;
Molecular Dynamics Simulation
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Mutagenesis, Site-Directed
;
Naphthoquinones/therapeutic use*
;
Protease Inhibitors/therapeutic use*
;
Protein Structure, Tertiary
;
Recombinant Proteins/isolation & purification*
;
SARS-CoV-2/isolation & purification*
6.Advances in core protein allosteric modulators
Qianqian GAO ; Kailin HAN ; Guocheng WANG ; Tao LU
Journal of China Pharmaceutical University 2019;50(5):516-522
The core protein allosteric modulator targets the core protein and inhibits hepatitis B virus(HBV)replication by regulating the formation of covalently closed circular DNA(cccDNA), which is expected to completely cure hepatitis B and overcome the drug resistance of nucleoside drugs. This paper reviews the replication process of HBV, the function of core proteins, the mechanism, classification and research progress of core protein allosteric modulators, lists 12 drugs, and summarizes their mechanisms, categories, chemical structures, safety, anti-HBV effects, combined drug use, etc. In addition, the advantages and problems of core protein allosteric modulators are discussed to provide references for the development of new anti-HBV drugs.
7. Construction and in vitro verification of a new humanized anti-CD19 CAR-T cells with high affinity
Changxiao ZHANG ; Hai CHENG ; Xiao HAN ; Kunming QI ; Wei CHEN ; Qingyun WU ; Jiang CAO ; Kailin XU
Chinese Journal of Hematology 2018;39(6):465-470
Objective:
To construct humanized anti-CD19 chimeric antigen receptor T cells and investigate its ability to kill leukemia cells in vitro and in vivo.
Methods:
Humanized anti-human CD19 antibody with a high affinity was obtained based on mouse anti-human CD19 antibody (FMC63). Humanized CD19 CAR-T cells (hCART19) were constructed through transfection of lentivirus carrying a CAR sequence of humanized anti-CD19 scFv into human peripheral CD3+ T cells. The ability of hCART19 to kill leukemia cells and secrete cytokines was detected by LDH release assay and ELISA. The in vivo tumor-killing effect of hCART19 was evaluated in a leukemia mouse model.
Results:
Several different humanized CD19 single-chain antibodies which were constructed by IMGT database were expressed in the eukaryotic expression vector and purified followed by acquiring humanized CD19 antibody (Clone H3L2) with similar binding ability to FMC63. Humanized CD19 CAR lentivirus vector was constructed and transfected into T cells to obtain hCART19 cells. The LDH release experiment confirmed that the killing rate of target cells was increased gradually along with the increased E/T ratio. When the ratio of E/T was 10∶1, the killing rate of target cells by hCART19 reached a maximum. When Raji cells were used as target cells, the hCART19 cells group had a significantly higher kill rate [(87.56±1.99)%] than the untransduced T cells group [(19.31±1.16)%] and the control virus transduced T cells group [(21.35±1.19)%](
8.Effect of down-regulation of growth arrest and DNA damage inducible protein 45β on PC9 lung adenocarcinoma cells.
Hao HU ; Kailin QUE ; Hao PENG ; Jia LIU ; Cheng HAN ; Na ZHANG ; Tao HOU ; Chunhong HU ; Jin'an MA
Journal of Central South University(Medical Sciences) 2018;43(11):1209-1215
To explore the effect of down-regulation of growth arrest and DNA damage inducible protein 45β (GADD45β) on the PC9 lung adenocarcinoma cells.
Methods: GADD45β gene siRNA sequence was designed and synthesized, which was transfected into PC9 lung adenocarcinoma cells through lentivirus transfection. Quantitative real-time PCR (qRT-PCR) and Western blot are used to examine the mRNA and protein levels of GADD45β in PC9 cells before and after the transfection. Annexin V-allophycocyanin (APC) double-staining flow cytometry was used to detect the apoptosis level after the transfection. The intracellular DNA content after transfection was detected by flow cytometry. The percentage of the cells at each period of cell cycle was calculated, and the effect of RNA interference on the cell growth were analyzed. The effects of RNA interference on the tumor-formation ability of cells were tested by counting the number of clones. MTT assay was used to test the half maximal inhibitory concentration (IC50) of PC9 cells for gefitinib.
Results: The 5'-AAATCCACTTCACGCTCAT-3' sequence was identified as the effective sequence for GADD45β gene RNA interference. The mRNA and protein expression levels of GADD45β were markedly decreased (both P<0.05) at 48 h after transfection of GADD45β-siRNA, which resulted in the increased apoptosis rate (P<0.05), decreased tumor clone number (P<0.05) and increased percentage of PC9 cell at the S stage and G2/M stage (P<0.05). The IC50 for gefitinib was decreased obviously (P<0.05).
Conclusion: Down-regulation of GADD45β can reduce the colony-forming ability of PC9 cells, promote the cell apoptosis, and enhance the sensitivity of PC9 cells to gefitinib.
Adenocarcinoma of Lung
;
Antigens, Differentiation
;
genetics
;
metabolism
;
Antineoplastic Agents
;
pharmacology
;
Apoptosis
;
drug effects
;
Cell Line, Tumor
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Cell Proliferation
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Down-Regulation
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Gefitinib
;
pharmacology
;
Humans
;
RNA, Small Interfering
9. Effects of PSMB5 on proliferation and bortezomib chemo-resistance in human myeloma cells and its related molecular mechanisms
Huimin MO ; Qingyun WU ; Danyang HAN ; Rui LIU ; Xun MA ; Ping ZHOU ; Kailin XU
Chinese Journal of Hematology 2017;38(12):1053-1057
Objective:
To investigate the effects of proteasome beta 5 subunit (PSMB5) on proliferation and bortezomib (BTZ) chemo-sensitivity of multiple myeloma (MM) and its related molecular mechanisms.
Methods:
We used two MM cell lines, RPMI 8226 and BTZ drug-resistant cell line RPMI 8226/BTZ100 (hereinafter referred to as BTZ100) , as the research object. PSMB5 was overexpressed or knocked down in two myeloma cell lines via lentivirus transfection. CCK8 assay was used to detect the impact of PSMB5 on cell viability and bortezomib sensitivity in human myeloma cells; Using flow cytometry to test the effects of PSMB5 on apoptosis rate of human myeloma cells under the treatment of bortezomib; Apoptosis-related gene expression of Bax, Bcl-2, p-Akt and cleaved caspase-3 were detected by Western blot.
Results:
①PSMB5 overexpression and knockdown were successfully constructed in RPMI 8226 and BTZ100 cells. ②PSMB5 expression was positively correlated with cell proliferation of RPMI 8226 and BTZ100 cells (
10.Prokaryotic expression and purification of GST-NRP-1 fusion protein
Zhengxiang HAN ; Mengjin ZHANG ; Jie XU ; Hongmei WANG ; Xiuping DU ; Chong CHEN ; Kailin XU
Chinese Journal of Immunology 2015;(10):1370-1374
Objective:To construct GST-tagged human NRP-1 fusion protein expression vector and induce its expression in Escherichia coli ( E.coli) ,then carry on inclusion body refolding and purification so as to obtain GST-NRP-1 fusion protein.Methods:NRP-1 gene was amplified by RT-PCR and inserted into pCR-blunt vector.Then the reconstructed plasmid was inserted into prokaryotic expression vector pGEX-4T-1.The constructed pGEX-4T-1-NRP-1 expression vector was transformed into BL21 cells and induced by i-sopropyl-β-D-thiogalactoside ( IPTG).Bacterial bodies were disrupted by sonication.Then the soluble fraction of fusion proteins were verified by Western blot and purified by Glutathione Sepharose 4B after inclusion body refolding.Results: The NRP-1 gene fragment was amplified by RT-PCR and inserted into pCR-blunt vector.Fusion protein expression vector pGEX-4T-1-NRP-1 was constructed suc-cessfully.After transformation, GST-NRP-1 expression vector was detected in BL21 cells and obtained purifying protein after refolding.Conclusion:The plasmid GST-NRP-1 was constructed successfully and laid basis for subsequent studies.

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