Brasilicardin A (BraA) is a natural diterpene glycoside isolated from the pathogenic actinomycete Nocardia brasiliensis IFM 0406 with highly potent immunosuppressive activity (IC₅₀=0.057 μg/mL). BraA potently inhibits the uptake of amino acids that are substrates for amino acid transport system L of T cells, which is different from the existing clinical immunosuppressants. BraA is more potent in a mouse mixed lymphocyte reaction and less toxic against various human cell lines compared with the known clinical immunosuppressants, such as cyclosporin A, ascomycin and tacrolimus. Therefore, BraA attracted more attention as a new promising immunosuppressant. However, the development of this promising immunosuppressant as drug for medical use is so far hindered because BraA has the unusual and synthetically challenging skeleton and shows the low-yield production in the natural pathogenic producer. This review introduces the molecular structure of BraA, its activity, mechanism of action, chemical synthesis of BraA analogs, heterologous expression of gene cluster, and an application of combining microbial and chemical synthesis for production of BraA, with the aim to facilitate the efficient production of BraA and its analogs.
Animals ; Mice ; Humans ; Immunosuppressive Agents/chemistry* ; Aminoglycosides/pharmacology* ; Cyclosporine/pharmacology* ; Diterpenes

OBJECTIVE: To evaluate the efficacy, safety and relapse of cyclosporine A (CsA) and CsA combined with corticosteroid (CS) as the frontline therapy for patients with newly diagnosed acquired pure red cell aplasia (aPRCA). METHODS: The clinical features, treatment responses, relapses and clinical outcomes of patients with newly diagnosed aPRCA in Peking Union Medical College Hospital (PUMCH) from January 2015 to May 2020 were analyzed retrospectively. All the enrolled patients had been treated with either CsA or CsA+CS for at least 6 months and had been followed up for at least 12 months, with complete clinical data and consent forms. RESULTS: 96 patients including 72 treated with CsA and 24 treated with CsA+CS were enrolled. With comparable baseline characteristics and follow-up periods, patients treated with CsA or with CsA+CS had similar overall response rates (ORRs) and complete response rates (CRRs) at the 3rd, 6th and 12th month and at the end of follow-up (P>0.05). Meanwhile, no significant difference was found between the two groups in the optimal ORR, optimal CRR, time to response or time to complete response. CsA+CS and CsA groups had similar adverse event (AE) rates, but CsA+CS group had higher CS-related infection rate (P <0.05). One patient in CsA+CS group died of multiple infections. As for the relapse, the two groups had compatible relapse rates at different time points, time to relapse, overall relapse rate and relapse-free survival (P>0.05). CsA exposure time, rather than different therapy regimens, was the only influence factor for either ORR or relapse rate (P <0.05). CONCLUSION CsA monotherapy has similar efficacy, AE rate and relapse rate as compared with CsA+CS for patients with newly diagnosed aPRCA, and shows less CS-related AEs such as infection.
Humans ; Cyclosporine/therapeutic use* ; Retrospective Studies ; Red-Cell Aplasia, Pure/drug therapy* ; Adrenal Cortex Hormones/therapeutic use* ; Remission Induction ; Treatment Outcome ; Immunosuppressive Agents/therapeutic use*

OBJECTIVE: To evaluate the value of pharmacogenetic testing for improving the efficacy and safety of treatment with cyclosporine, tacrolimus, and cyclophosphamide (CTX) for PLA2R-related membranous nephropathy and for determing individualized and precise treatment plans for the patients. METHODS: A total of 63 patients with PLA2R-related membranous nephropathy hospitalized in the Department of Nephrology at our hospital from January, 2019 to October, 2021 were enrolled in this study. Thirty-three of the patients underwent pharmacogenetic testing before taking the immunosuppressive drugs selected based on the results of genetic screening for sensitive targets, and the other 30 patients were empirically given immunosuppressive drugs according to the guidelines (control group). The clinical efficacy and adverse effects of the immunosuppressive drugs were analyzed for all the patients. The two groups of patients were compared for demographic and biochemical parameters including 24-h urine protein, serum albumin, renal function, and serum anti-phospholipase A2 receptor antibody both before and at 3 months after the beginning of the treatment. RESULTS: Among the 33 patients undergoing pharmacogenetic testing, 51.5% showed a GG genotype for cyclosporine, and 61.6% had an AG genotype for tacrolimus; for CTX, 51.5% of the patients showed a homozygous deletion and 63.6% had an AA genotype. After treatment for 3 months, serum anti-phospholipase A2 receptor antibody, 24-h urine protein, and serum albumin levels were significantly improved in pharmacogenetic testing group as compared with the control group (P < 0.05). CONCLUSION Individualized and precise administration of immunosuppressive drugs based on pharmacogenetic testing better controls proteinuria and serum antiphospholipase A2 receptor antibodies and increases serum albumin level in patients with PLA2R-related membranous nephropathy.
Humans ; Autoantibodies ; Cyclosporine/therapeutic use* ; Glomerulonephritis, Membranous/diagnosis* ; Homozygote ; Immunosuppressive Agents/therapeutic use* ; Pharmacogenomic Testing ; Receptors, Phospholipase A2 ; Sequence Deletion ; Serum Albumin ; Tacrolimus/therapeutic use*

OBJECTIVE: To compare the efficacy of eltrombopag combined with cyclosporine A (CsA) and CsA alone in patients with transfusion-dependent non-severe aplastic anemia (TD-NSAA). METHODS: The clinical data of 76 patients with treatment-naive TD-NSAA in Ningde Municipal Hospital of Ningde Normal University and Affiliated Hospital of Nantong University from December 2017 to June 2021 were retrospectively analyzed. Among them, 45 cases were treated with eltrombopag combined with CsA, and 31 patients with compatible baseline characters were treated with CsA alone. The efficacy of patients between the two groups was compared, and the factors affecting the curative effects were also analyzed. RESULTS: There were significant differences in hematological response (HR) and complete response(CR) rates between the two groups at 3, 6, 12 months, and follow-up endpoint of treatment (P<0.05). With the prolongation of eltrombopag treatment time, the curative effect increased gradually, and the patients achieved more CR and HR rates by the end of the follow-up period. Simultaneously, with the increase in the maximum stable dose of eltrombopag, the HR rate increased gradually. The megakaryocyte count in eltrombopag group was higher than that in control at 6 and 12 months (P<0.05). Compared with the control group, the median time of platelet transfusion independence in eltrombopag group was more shorter (P=0.018), and the median platelets transfusion volume was lower (P=0.009). At 3, 6, 12 months after eltrombopag, the change of platelet in eltrombopag group was higher than that in the control group (P<0.05). Analysis of related factors affecting the efficacy showed that sex, age, iron overload, platelet count before treatment had no effect on the efficacy, and the median maximum stable dosage and the administration period for eltrombopag were related to the curative effect. The patients of eltrombopag group experienced adverse events of varying degrees, but the reactions were mild and mostly tolerated. CONCLUSION Eltrombopag can effectively improve the hematopoietic response and promote platelet recovery for TD-NSAA patients with relatively more residual hematopoietic cells, and it is safe and well tolerated.
Humans ; Anemia, Aplastic/therapy* ; Retrospective Studies ; Treatment Outcome ; Cyclosporine/therapeutic use* ; Immunosuppression Therapy ; Immunosuppressive Agents/therapeutic use*

Humans ; Cyclosporine/therapeutic use* ; Anemia, Aplastic/drug therapy* ; Neoplasms/drug therapy* ; Immunosuppressive Agents/therapeutic use* ; Benzoates/therapeutic use*

Objective: To reassess the predictors for response at 6 months in patients with severe or very severe aplastic anemia (SAA/VSAA) who failed to respond to immunosuppressive therapy (IST) at 3 months. Methods: We retrospectively analyzed the clinical data of 173 patients with SAA/VSAA from 2017 to 2018 who received IST and were classified as nonresponders at 3 months. Univariate and multivariate logistic regression analysis were used to evaluate factors that could predict the response at 6 months. Results: Univariate analysis showed that the 3-month hemoglobin (HGB) level (P=0.017) , platelet (PLT) level (P=0.005) , absolute reticulocyte count (ARC) (P<0.001) , trough cyclosporine concentration (CsA-C0) (P=0.042) , soluble transferrin receptor (sTfR) level (P=0.003) , improved value of reticulocyte count (ARC(△)) (P<0.001) , and improved value of soluble transferrin receptor (sTfR(△)) level (P<0.001) were related to the 6-month response. The results of the multivariate analysis showed that the PLT level (P=0.020) and ARC(△) (P<0.001) were independent prognostic factors for response at 6 months. If the ARC(△) was less than 6.9×10(9)/L, the 6-month hematological response rate was low, regardless of the patient's PLT count. Survival analysis showed that both the 3-year overall survival (OS) [ (80.1±3.9) % vs (97.6±2.6) %, P=0.002] and 3-year event-free survival (EFS) [ (31.4±4.5) % vs (86.5±5.3) %, P<0.001] of the nonresponders at 6 months were significantly lower than those of the response group. Conclusion: Residual hematopoietic indicators at 3 months after IST are prognostic parameters. The improved value of the reticulocyte count could reflect whether the bone marrow hematopoiesis is recovering and the degree of recovery. A second treatment could be performed sooner for patients with a very low ARC(△).
Anemia, Aplastic/drug therapy* ; Antilymphocyte Serum/therapeutic use* ; Cyclosporine/therapeutic use* ; Humans ; Immunosuppression Therapy ; Immunosuppressive Agents/therapeutic use* ; Prognosis ; Receptors, Transferrin/therapeutic use* ; Retrospective Studies ; Treatment Outcome

Objective: To study the metabolic characteristics of anti-human T-cell porcine immunoglobulin (p-ATG) in patients with severe aplastic anemia (SAA) . Methods: For patients with SAA treated with p-ATG combined cyclosporine A (CsA) immunosuppressants between February 2017 and December 2017, the p-ATG dose was 20 mg·kg(-1)·d(-1) over 12 h of intravenous administration for 5 consecutive days. The blood concentration of p-ATG was detected by the three-antibody sandwich ELISA method, the pharmacokinetic analysis software was fitted, and the second-chamber model method was used to calculate the pharmacokinetic parameters and plot the pharmacokinetic curve. Adverse events were recorded and the hematologic reactions were determined at 6 months after treatment. Results: Sixteen patients with SAA treated with p-ATG were enrolled, including 8 females and 8 males, with a median age of 22 years (range, 12 to 49 years) and a median weight of 62.5 kg (range, 37.5 to 82.0 kg) . The pharmacokinetics of p-ATG could be evaluated in 14 cases. p-ATG is distributed in vivo as a two-chamber model, with an average drug concentration peak (T(max)) of (5.786±2.486) days, a peak concentration (C(max)) of (616±452) mg/L, and a half-life of (10.479±8.242) days. The area under the drug time curve (AUC) was (5.807±3.236) mg/L·d. Six months after treatment, 8 of 14 patients received a hematologic response; the AUC (0-t) of the effective group and ineffective groups was (7.50±3.26) mg/L·d vs (4.50±2.18) mg/L·d, and the C(max) was (627±476) mg/L vs (584±382) mg/L, respectively. Conclusion: The plasma concentration of p-ATG reached a peak after 5 days of continuous infusion, and then decreased slowly, with a half-life of 10.479 days, and the residual drug concentration was detected in the body 60 days after administration. A relationship between drug metabolism and efficacy and adverse reactions could not be determined.
Anemia, Aplastic/drug therapy* ; Animals ; Antilymphocyte Serum/therapeutic use* ; Cyclosporine/therapeutic use* ; Female ; Humans ; Immunoglobulins/therapeutic use* ; Immunosuppression Therapy ; Immunosuppressive Agents/therapeutic use* ; Male ; Swine ; T-Lymphocytes ; Treatment Outcome

Adult ; Cyclosporine ; Glomerulosclerosis, Focal Segmental/drug therapy* ; Humans ; Leflunomide/therapeutic use* ; Nephrosis, Lipoid/drug therapy* ; Nephrotic Syndrome ; Steroids

OBJECTIVE: To establish a stable mouse model of acquired aplastic anemia. METHODS: Female BALB/C mice aged 6 months were intraperitoneally injected with cyclophosphamide and cyclosporine for 14 days. The number of peripheral blood cells, the concentration of hemoglobin, the number of bone marrow nucleated cells, bone marrow smear, bone marrow pathological sections and other indexes were observed. RESULTS: In BALB/C mice injected intraperitoneally with cyclophosphamide and cyclosporine, the number of peripheral blood cells and the concentration of hemoglobin were significantly decreased, especially the white blood cells and platelets. Bone marrow smear showed a significant decrease in the number of nucleated cells and bone marrow hyperplasia. Bone marrow pathology showed decreased hematopoietic cells and increased non-hematopoietic cells such as adipocytes. CONCLUSION The mouse model with intraperitoneal injection of cyclophosphamide and cyclosporine can meet the diagnostic criteria of acquired aplastic anemia, which can be used as a mouse model for the study of the pathogenesis and treatment of acquired aplastic anemia.
Anemia, Aplastic ; Animals ; Bone Marrow ; Cyclophosphamide ; Cyclosporine ; Female ; Mice ; Mice, Inbred BALB C

OBJECTIVES: This study aimed to explore the specific mechanism, mediated by the reactive oxygen species (ROS) and PINK1/Parkin pathway, of the mitochondrial autophagy of human periodontal ligament cells (hPDLCs) under starvation conditions. METHODS: hPDLCs were isolated and cultured from normal periodontal tissues. Earle's balanced salt solution (EBSS) was used to simulated a starvation environment and thus stimulate hPDLCs mitochondrial autophagy. N-Acetyl-L-cysteine (NAC) was used to inhibit ROS production to explore the role of ROS in hPDLC mitochondrial autophagy. Cyclosporin A was used to inhibit the PINK1/Parkin pathway to study the role of ROS and the PINK1/Parkin pathway in hPDLCs activation under starvation. The mitochondrial membrane potential was detected by flow cytometry with a JC-1 mitochondrial membrane potential detection kit. The morphological structure of mitochondria and the formation of mitochondrial autophagosome were observed by transmission electron microscopy. Mito tracker red cmxros and lyso tracker green staining were used to observe the localization of mitochondria and lysosomes. The formation intensity of ROS was detected with a DCFH-DA ROS fluorescent probe. The expression levels of mitochondrial autophagy genes (Tomm20 and Timm23) and the PINK1/Parkin pathway were detected by real-time quantitative polymerase chain reaction (RT-qPCR). The expression levels of mitochondrial autophagy proteins (Tomm20 and Timm23) and PINK1/Parkin protein were detected by Western blot. RESULTS: EBSS starvation for 30 min induced the strongest activation of hPDLCs mitochondrial autophagy, increased the expression of ROS, downregulated the expression of mitochondrial autophagy-related genes (Tomm20 and Timm23) (P<0.001), and upregulated the PINK1/Parkin pathway (P<0.001). After NACinhibited ROS production, mitochondrial autophagy was also inhibited. Meanwhile, the expression of Tomm20 and Timm23 was upregulated (P<0.001 and P<0.05), and the expression of the PINK1/parkin pathway (P<0.001 and P<0.05) was down regulated. When cyclosporin A inhibited the expression of the PINK1/Parkin pathway (P<0.05 and P<0.05), it reversed the mitochondrial autophagy of hPDLCs (P<0.001 and P<0.01) and also upregulated the expression of Tomm20 and Timm23 (P<0.001 and P<0.01). CONCLUSIONS ROS enhanced the mitochondrial autophagy of hPDLCs primarily through the PINK1/Parkin pathway under starvation conditions.
Humans ; Mitophagy/genetics* ; Reactive Oxygen Species/metabolism* ; Periodontal Ligament/metabolism* ; Cyclosporine ; Protein Kinases/metabolism* ; Ubiquitin-Protein Ligases/metabolism*