Adrenoleukodystrophy ; genetics ; therapy ; Humans ; Lovastatin ; pharmacology

AIM: To determine the IPP origin of the naphthoquinones (NQs) in Rubia cordifolia, and to evaluate the effects of methyl jasmonate (MeJA) treatment, MEP, and MVA pathway inhibitor treatment on the accumulation of anthraquinones (AQs) and NQs in cell suspension cultures of R. cordifolia. METHODS: Cell suspension cultures of R. cordifolia were established. Specific inhibitors (lovastatin and clomazone) and MeJA were supplied to the media, respectively. Treated cells were sampled every three days. Content determination of purpurin (AQs) and mollugin (NQs) were carried out using RP-HPLC. The yield of the two compounds was compared with the DMSO-supplied group and the possible mechanism was discussed. RESULTS: Lovastatin treatment increased the yield of purpurin and mollugin significantly. Clomazone treatment resulted in a remarkable decrease of both compounds. In the MeJA-treated cells, the purpurin yield increased, meanwhile, the mollugin yield decreased compared with control. CONCLUSION The IPP origin of mollugin in R. cordifolia cell suspension cultures was likely from the MEP pathway. To explain the different effects of MeJA on AQs and NQs accumulation, studies on the regulation and expression of the genes, especially after prenylation of 1,4-dihydroxy-2-naphthoic acid should be conducted.
Acetates ; pharmacology ; Anthraquinones ; metabolism ; Cell Culture Techniques ; Cells, Cultured ; Cyclopentanes ; pharmacology ; Isoxazoles ; pharmacology ; Lovastatin ; pharmacology ; Oxazolidinones ; pharmacology ; Oxylipins ; pharmacology ; Pyrans ; metabolism ; Rubia ; drug effects ; metabolism

BACKGROUNDAdvances in the understanding of cardiovascular pathogenesis have highlighted that inflammation plays a central role in atherosclerotic coronary heart disease. Therefore, exploring pharmacologically based anti-inflammatory treatments to be used in cardiovascular therapeutics is worthwhile to promote the discovery of novel ways of treating cardiovascular disorders.

METHODSThe myocardial cell line H9c2(2-1) was exposed to lipopolysaccharide (LPS) in culture and resulted in a cellular pro-inflammation status. miR-21 microRNA levels were detected using quantitative real-time polymerase chain reaction (Q-RT-PCR). The influence of lovastatin on miR-21 under normal and pro-inflammatory conditions was tested after being added to the cell culture mixture for 24 hours. Conditional gene function of two predicted cardiovascular system relevant downstream targets of miR-21, protein phosphatase 1 regulatory subunit 3A (PPP1R3A) and signal transducer and activator of transcription 3 (STAT3), were analyzed with immunoblotting.

RESULTSForty-eight hours of LPS treatment significantly increased the miR-21 to 170.71%± 34.32% of control levels (P = 0.002). Co-treatment with lovastatin for 24 hours before harvesting attenuated the up-regulation of miR-21 (P = 0.013). Twenty-four hours of lovastatin exposure up-regulated PPP1R3A to 143.85%± 21.89% of control levels in cardiomyocytes (P = 0.023). Lovastatin up-regulated the phosphorylation level of STAT3 compared to the background LPS pretreatment (P = 0.0077), this effect was significantly (P = 0.018) blunted when miR-21 was functionally inhibited.

CONCLUSIONSmiR-21 plays a major role in the regulation of the cellular anti-inflammation effects of lovastatin.

Blotting, Western ; Cell Line ; Humans ; Lipopolysaccharides ; pharmacology ; Lovastatin ; pharmacology ; MicroRNAs ; genetics ; Myocardium ; metabolism ; Myocytes, Cardiac ; drug effects ; metabolism ; Phosphoprotein Phosphatases ; metabolism ; Phosphorylation ; STAT3 Transcription Factor ; metabolism

OBJECTIVETo study the effects and mechanism of lovastatin on cell cycle phase and proliferation of cultured human glomerular mesangial cells in vitro.

METHODSHMC proliferation was determined by 3H-Thymidine incorporation. HMC cell cycle was measured by flow cytometric analysis.

RESULTSLovastatin was found to inhibit HMC proliferation in a dose-dependent manner. Flow cytometric analysis demonstrated that lovstatin induced G1/S transition arrest. Concomitant addition of mevalonate or farnesol restored all the inhibitory effect of lovstatin on HMC.

CONCLUSIONLovastatin is a HMC proliferation inhibitor. It provides an experimental evidence for re-evaluate renal protective effect of HRI, which has already been widely used in clinical treatment.

Cell Cycle ; drug effects ; Cell Division ; drug effects ; Cells, Cultured ; Dose-Response Relationship, Drug ; Flow Cytometry ; Glomerular Mesangium ; cytology ; Humans ; Hydroxymethylglutaryl-CoA Reductase Inhibitors ; pharmacology ; Kinetics ; Lovastatin ; pharmacology

OBJECTIVETo investigate the effect of lovastatin on proliferation and extracellular matrix secretion of hepatic stellate cells in vitro.

METHODSRat hepatic stellate cells were incubated with different concentration of lovastatin and geranyl geranypyrophosphate. Cell proliferation was assessed by MTT colorimetric assay. Cell cycle was analysed by flow cytometry. Type IV collagen and laminin were determined by ELISA, and c-jun and c-fos expression by immunocytochemistry and computer video text analysis system.

RESULTSAddition of 0.1 to 50 micromol/L lovastatin into culture medium had no toxicity to hepatic stellate cells, but could significantly inhibit hepatic stellate cell proliferation and provoke G0/G1 phase arrest in dose-dependent manner, and could also markedly inhibit the c-jun and c-fos expression and type IV collagen and laminin secretion, which could partly be antagonized by geranyl geranypyrophosphate.

CONCLUSIONSLovastatin can significantly inhibit hepatic stellate cell proliferation and type IV collagen and laminin secretion, which might be partly related to its inhibitory effect on geranyl geranypyrophosphate formation.

Animals ; Cell Cycle ; Cell Division ; Cell Proliferation ; drug effects ; Cells, Cultured ; Collagen Type IV ; Extracellular Matrix ; secretion ; Hepatic Stellate Cells ; drug effects ; secretion ; Lovastatin ; pharmacology ; Rats

The present study was designed to isolate and characterize a purified extract from Fusarium solani FG319, termed MFS (Metabolite of Fusarium solani FG319) that showed anti-atherosclerosis activity by inhibiting 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase. Response surface methodology (RSM) was employed to achieve an improved yield from the fermentation medium. The inhibiting effect of the isolate, MFS, on HMG-CoA reductase was greater than that of the positive control, lovastatin. The average recovery of MFS and the relative standard deviation (RSD) ranged between 99.75% to 101.18%, and 0.31% to 0.74%, respectively. The RSDs intra- and inter-assay of the three samples ranged from 0.288% to 2.438%, and from 0.934% to 2.383%, respectively. From the RSM, the concentration of inducer, cultivation time, and culture temperatures had significant effects on the MFS production, with the effect of inducer concentration being more pronounced that other factors. In conclusion, the optimal conditions for the MFS production were achieved using RSM and that MFS could be explored as an anti-atherosclerosis agent based on its ability to inhibit HMG-CoA reductase.
Analysis of Variance ; Biological Factors ; isolation & purification ; pharmacology ; Chromatography, High Pressure Liquid ; Fermentation ; physiology ; Fusarium ; metabolism ; Hydroxymethylglutaryl CoA Reductases ; metabolism ; Hydroxymethylglutaryl-CoA Reductase Inhibitors ; isolation & purification ; pharmacology ; Lovastatin ; pharmacology ; Nucleic Acid Amplification Techniques

BACKGROUNDLactate dehydrogenase (LDH) is a crucial regulator of energy metabolism in many organs including the heart. Lovastatin is widely used in prevention and treatment of coronary heart disease and is a drug with substantial metabolic influences. Our study aimed to determine the activities of the lactate dehydrogenase A and B (LDHA and LDHB) genes following lovastatin treatment.

METHODSThe rat myocardial cell line H9c2(2-1) in culture was exposed to 100 nmol/L lovastatin for 24 hours or for five days. The functions of the LDHA and LDHB genes were examined at the transcriptional (mRNA) level with quantitative real-time polymerase chain reaction (Q-RT-PCR), and at the translational (protein) level with immunoblotting.

RESULTSWhen compared with control levels, the LDHA mRNA went up by (151.65 ± 16.72)% (P = 0.0132) after 24 hours and by (175.28 ± 56.54)% (P = 0.0366) after five days of lovastatin treatment. Although 24 hours of lovastatin treatment had no significant effects on LDHB mRNA levels, when the treatment was extended to five days, LDHB mRNA levels were significantly down-regulated to (63.65 ± 15.21)% of control levels (P = 0.0117). After 24 hours of treatment with lovastatin, there were no significant changes in protein levels of either LDHA or LDHB. When treatment time was extended to five days, the protein levels of LDHA were up-regulated by (148.65 ± 11.81)% (P = 0.00969), while the protein levels of LDHB were down-regulated to (64.91 ± 5.47)% of control levels (P = 0.0192).

CONCLUSIONSLovastatin affects gene activities of LDHA and LDHB differently, which may reveal novel pharmacological effects of lovastatin.

Animals ; Anticholesteremic Agents ; pharmacology ; Blotting, Western ; Cell Line ; Isoenzymes ; genetics ; metabolism ; L-Lactate Dehydrogenase ; genetics ; metabolism ; Lovastatin ; pharmacology ; Myocytes, Cardiac ; drug effects ; enzymology ; Rats ; Reverse Transcriptase Polymerase Chain Reaction

In order to investigate the anti-tumor activity of 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitors and the mechanism underlying the cell proliferation and apoptosis modulated in myeloma cells, the effects of mevastatin, an HMG-CoA reductase inhibitor, on cell growth, cell cycle progression and apoptosis in U266 human multiple myeloma (MM) cell line in vitro were explored by MTT colorimetric assay, morphologic observation, flow cytometry, DNA gel electrophoresis, and RT-PCR. The results demonstrated that mevastatin inhibited the growth of U266 cells in time- and dose-dependent manners. Cell cycle analysis showed that U266 cells underwent G(0)/G(1) arrest under exposure to mevastatin, but it did not affect p27 expression at both mRNA and protein level. Morphologic observations revealed cytoplasm shrinkage, nuclear condensation and fragmentation in mevastatin-treated cells, and fraction of annexin V(+)PI(-) cells increased significantly in the presence of the agent as determined by flow cytometric assay. In addition, mevastatin caused the collapse of mitochondrial transmembrane potential (Deltapsim), induced DNA fragmentation, and down-regulated the mRNA expression of bcl-2. The growth-inhibitory, cell cycle arresting, and proapoptotic effects of mevastatin in U266 cells could be effectively reversed by the addition of mevalonate (MVA), the immediate endproduct of the reaction catalyzed by HMG-CoA reductase. It is concluded that mevastatin suppresses proliferation by inducing G(0)/G(1) phase arrest and triggering apoptosis via down-regulation of bcl-2 and reduction of Deltapsim, which may be attributed to the inhibition of MVA pathway by mevastatin. Statins including mevastatin may find their future application in the treatment of MM.
Apoptosis ; drug effects ; Cell Division ; drug effects ; Cell Line, Tumor ; G1 Phase ; drug effects ; Genes, bcl-2 ; Humans ; Hydroxymethylglutaryl-CoA Reductase Inhibitors ; pharmacology ; Lovastatin ; analogs & derivatives ; pharmacology ; Multiple Myeloma ; drug therapy ; pathology

Heme oxygenase-1 (HO-1) is a cellular stress protein, and its expression plays an important regulatory role in a lot of physiological and pathological processes. Although the expression of HO-1 in most tissues of body is low, a number of clinical and pharmacological experiments have proved that many compounds can induce HO-1 expression. The increase of HO-1 expression is the result of regulating different signaling pathways and transcription factors, and this induction of HO-1 is suggested to be partially therapeutic efficacy of these compounds. This article summarizes some kinds of compounds in this field of research at home and abroad over the last 10 years, and provides a brief analysis of the mechanism.
Animals ; Antineoplastic Agents ; pharmacology ; Antioxidants ; pharmacology ; Coumarins ; pharmacology ; Drugs, Chinese Herbal ; pharmacology ; Enzyme Induction ; drug effects ; Gene Expression Regulation, Enzymologic ; Heme Oxygenase-1 ; genetics ; metabolism ; Humans ; Lovastatin ; pharmacology ; Nitric Oxide ; pharmacology ; Peptide Hormones ; pharmacology ; Probucol ; pharmacology ; Signal Transduction ; Transcription Factors ; metabolism

OBJECTIVETo study the effects and mechanism of lovastatin on cell proliferation and expression of proinflammatory cytokines in cultured human glomerular mesangial cells.

METHODSThe influence of lovastatin on HMC proliferation was evaluated with 3H-thymidine incorporation. mRNA expression of proinflammatory cytokines (IL-1 beta, IL-6, TNF-alpha, and MCP-1) and activation of NF-kappa B of HMC were measured using Reverse transcription-polymerase chain reaction (RT-PCR) and electrophoretic mobility shift assay (EMSA) respectively.

RESULTSLovastatin was found to have inhibitory effects on human mesangial cell (HMC) proliferation and lipopolysaccharide (LPS)-mediated human mesangine cell HMC mRNA expression of proinflammatory cytokines via activation of NF-kappa B. The effect of lovstatin on HMC could be prevented when the mevalonate and farnesol were added to the culture.

CONCLUSIONLovastatin may decrease HMC proliferation and production of proinflammatory cytokines through the inhibition of NF-kappa B activation. This provided experimental evidence for further evaluation of the renal protective effect of HRI, suggesting that it may be a potent agent for prevention of progressive renal diseases aside from its lipid-lowering effect.

Cell Division ; drug effects ; Cell Survival ; drug effects ; Cells, Cultured ; Chemokine CCL2 ; analysis ; Glomerular Mesangium ; cytology ; drug effects ; Humans ; Interleukin-1 ; analysis ; Interleukin-6 ; analysis ; Lovastatin ; pharmacology ; NF-kappa B ; Reverse Transcriptase Polymerase Chain Reaction ; Tumor Necrosis Factor-alpha ; analysis