Mechanism of graphene-induced cytotoxicity: Role of endonucleases.

Graphene, a crystalline allotrope or carbon, presents numerous useful properties; however, its toxicity is yet to be determined. One of the most dramatic and irreversible toxic abilities of carbon nanomaterials is the induction of DNA fragmentation produced by endogenous cellular endonucleases. This study demonstrated that pristine graphene exposed to cultured kidney tubular epithelial cells is capable of inducing DNA fragmentation measured by terminal deoxynucleotidyl transferase dUTP nick end labeling (TUNEL) assay, which is usually associated with cell death. TUNEL (cell death) and endonuclease activity measured using a near infrared fluorescence probe was significantly higher in cells containing graphene aggregates detected by Raman spectroscopy. The elevation of TUNEL coincided with the increased abundance of heme oxygenase 1 (HO-1), heat shock protein 90 (HSP90), active caspase-3 and endonucleases (deoxyribonuclease I [DNase I] and endonuclease G [EndoG]), as measured by quantitative immunocytochemistry. Specific inhibitors for HO-1, HSP90, caspase-3, DNase I and EndoG almost completely blocked the DNA fragmentation induced by graphene exposure. Therefore, graphene induces cell death through oxidative injury, caspase-mediated and caspase-independent pathways; and endonucleases DNase I and EndoG are important for graphene toxicity. Inhibition of these pathways may ameliorate cell injury produced by graphene. Copyright © 2017 John Wiley & Sons, Ltd.

Catechols and 3-hydroxypyridones as inhibitors of the DNA repair complex ERCC1-XPF.

Catechol-based inhibitors of ERCC1-XPF endonuclease activity were identified from a high-throughput screen. Exploration of the structure-activity relationships within this series yielded compound 13, which displayed an ERCC1-XPF IC50 of 0.6 µM, high selectivity against FEN-1 and DNase I and activity in nucleotide excision repair, cisplatin enhancement and γH2AX assays in A375 melanoma cells. Screening of fragments as potential alternatives to the catechol group revealed that 3-hydroxypyridones are able to inhibit ERCC1-XPF with high ligand efficiency, and elaboration of the hit gave compounds 36 and 37 which showed promising ERCC1-XPF IC50 values of <10 µM.

EDTA-mediated inhibition of DNases protects circulating cell-free DNA from ex vivo degradation in blood samples.

OBJETIVES: The extracellular DNA occurring in plasma-EDTA and serum is a biomarker of growing interest, especially in prenatal diagnosis and oncology. The objectives of the present study were to compare the DNase activity in these specimens and to investigate its ex-vivo impact over the circulating cell-free DNA yield (ccfDNA), using the circulating cell-free fetal DNA (ccffDNA) as a tool. DESIGN AND METHODS: EDTA-plasma and serum from women bearing male fetus were submitted to an endogenous DNase activity assay based on qPCR hydrolysis probe degradation, they were treated with DNAse I to investigate the action of an exogenous nuclease and also submitted to different temperature conditions to investigate the temperature-dependent degradation of the ccffDNA. In all instances, all male ccffDNA were quantified by qPCR targeting the Y chromosome-specific sequence DYS-14. Moreover, a serial dilution of EDTA was added to nonanticoagulated plasma and serum before the endogenous DNAse activity assay, to investigate the EDTA-mediated inhibition of the blood's DNase. RESULTS: The endogenous nuclease activity was 14.9-fold higher in serum compared to EDTA-plasma. The DNAse I treatment did not alter the ccffDNA yields in EDTA-plasma, but completely degraded it in serum. The addition of increasing doses of EDTA to nonanticoagulated plasma and serum resulted in a stepwise inhibition of their nucleases activity. Finally, we observed a much more pronounced temperature-mediated decrease on the ccffDNA amount in serum compared to EDTA-plasma. CONCLUSION: The exogenous and endogenous DNases are more active in serum, the anticoagulant EDTA indirectly inhibits blood DNases, and consequently ccfDNA is protected from the blood's DNase preanalytical impact in EDTA-plasma.

Exposure of hepatocellular carcinoma cells to low-level As2O3 causes an extra toxicity pathway via L1 retrotransposition induction.

Various mechanisms have been proposed for toxicity and carcinogenesis pattern of arsenic, a naturally occurring metalloid. The extent to which the long interspersed element-1 (LINE-1) retrotransposon, an ubiquitous retroelement with autonomous mobility, can be influenced upon exposure to low-level arsenic remains to be elucidated. The aim of this study was to evaluate the possible effect of low-level As2O3 on L1 retrotransposition alteration in human hepatocellular carcinoma cells (HepG2). L1 retrotransposition in HepG2 cells was performed by the in vitro retrotransposition assay using an EGFP-tagged L1RP. Following determination of non-cytotoxic concentrations of arsenic by a MTT assay, the cells were transfected with pL1RP-EGFP and then exposed to 0.25, 0.50 and 0.75 µM of As2O3. The amount of EGFP and its copy number in retrotransposed cells were evaluated by FACS and qPCR analysis in treated vs. control cells, respectively. Significant increase in retrotransposition frequency was found after 12 days exposure to 0.50 and 0.75 µM of As2O3 by FACS analysis (P<0.05). Obtained results were further confirmed by real time PCR, which showed significant induction of retrotransposition in all mentioned concentrations. Our findings indicate that low-level long-term As2O3 exposure may pave activation of L1 retrotransposon.

Thiolated polycarbophil as an adjuvant for permeation enhancement in nasal delivery of antisense oligonucleotides.

The purpose of this study was to investigate the effect of thiolated polycarbophil as an adjuvant to enhance the permeation and improve the stability of a phosphorothioate antisense oligonucleotide (PTO-ODN) on the nasal mucosa. Polycarbophil-cysteine (PCP-Cys) was synthesized by the covalent attachment of L-cysteine to the polymeric backbone. Cytotoxicity tests were examined on human nasal epithelial cells from surgery of nasal polyps confirmed by histological studies. Deoxyribonuclease I activity in respiratory region of the porcine nasal cavity was analyzed by an enzymatic assay. The enzymatic degradation of PTO-ODNs on freshly excised porcine nasal mucosa was analyzed and protection of PCP-cysteine toward DNase I degradation was evaluated. Permeation studies were performed in Ussing-type diffusion chambers. PCP-Cys/GSH did not arise a remarkable mortal effect. Porcine respiratory mucosa was shown to possess nuclease activity corresponding to 0.69 Kunitz units/mL. PTO-ODNs were degraded by incubation with nasal mucosa. In the presence of 0.45% thiolated polycarbophil and 0.5% glutathione (GSH), this degradation process could be lowered. In the presence of thiolated polycarbophil and GSH the uptake of PTO-ODNs from the nasal mucosa was 1.7-fold improved. According to these results thiolated polycarbophil/GSH might be a promising excipient for nasal administration of PTO-ODNs.

2-nitro-5-thiosulfobenzoic acid as a novel inhibitor specific for deoxyribonuclease I.

Bovine pancreatic deoxyribonuclease I (bpDNase I) contains four cysteine residues forming two disulfide bonds. Though there are no free sulfhydryl groups, incubation of bpDNase I with 2-nitro-5-thiosulfobenzoic acid (NTSB) in the presence of Ca(2+) or Mg(2+) at pH 7.5 results in inactivation of the enzyme. Amino acid analysis shows that NTSB-treated bpDNase I still contains all 4 half-cystine residues. The only amino acid residues having reduced values are threonine and serine, indicating that these may be the reaction sites for NTSB. Plasmid scission assay and circular dichroism analysis reveal the structural integrity of the inactivated enzyme. Treatment of bpDNase I with NTSB does not result in fragmentation, as demonstrated by SDS-PAGE analysis. NTSB binds bpDNase I through covalent modification, since dialysis and gel filtration can not reverse the inactivation reaction. However, after dilution into an acid buffer of pH 4.7, the inactivated enzyme regains about 40% of its initial activity, suggesting a reversible inactivation by acid treatment. NTSB does not inactivate DNase II, ribonuclease, chymotrypsin and lysozyme, while it effectively inactivates rat parotid DNase I. These results strongly suggest that NTSB can be considered as a novel inhibitor specific for DNase I.

Actin cytoskeleton architecture and signaling in osmosensing.

Since the early days of cell volume regulation research, the role of actin cytoskeleton organization and rearrangement has attracted specific interest. Rapid modifications in actin dynamics and architecture have been described. They were shown to regulate cell volume changes, as well as regulatory volume decrease in a large variety of cell types, including hepatocytes, lymphocytes, fibroblasts, myocytes, and various tumor cells. Using microscopic and biochemical analyses, modifications of actin organization and polymerization dynamics were studied. This chapter summarizes the molecular approaches applied so far for the quantitative assessment of actin cytoskeleton dynamics in the various cell types. It demonstrates that rapid modifications of actin cytoskeleton dynamics regulated by specific signaling pathways play a functional role in cell volume regulation. It is concluded that studying actin polymerization dynamics and signaling represents a challenging tool for the understanding of osmosensing and osmosignaling regulation in cellular physiology.

Inhibition of deoxyribonuclease I by actin is to protect cells from premature cell death.

Deoxyribonuclease I (Dnase1) is the major extracellular endonuclease. It is secreted by digestive glands into the alimentary tract and into the plasma, lacrimal fluid and urine by hepatocytes, lacrimal glands and renal proximal tubular cells, respectively. In many species the activity of Dnase1 is inhibited by monomeric actin. However, the biological significance of this high affinity interaction is unknown. We generated a Dnase1 mutant with extremely reduced actin binding capacity. EGFP-constructs of wild-type and mutant Dnase1 were transfected into MCF-7 breast cancer cells and apoptosis or necrosis was induced by staurosporine or oxidative stress. During apoptosis faster chromatin fragmentation occurred in cells transfected with mutant Dnase1. When wt (wild-type)- or mutated Dnase1 were added to cells after induction of necrosis, faster chromatin degradation occurred in the presence of mutant Dnase1. Inclusion of actin under these conditions inhibited chromatin degradation by wt- but not by mutated Dnase1. Thus, inhibition of Dnase1 by actin may serve as a self-protection mechanism against premature DNA degradation during cell damage.

Aurintricarboxylic acid inhibits protein synthesis independent, sanguinarine-induced apoptosis and oncosis.

Sanguinarine, a benzophenanthridine alkaloid, has anticancer potential through induction of cell death. We previously demonstrated that sanguinarine treatment at a low concentration (1.5 microg/ml) induced apoptosis in K562 human erythroleukemia cells, and a high concentration (12.5 microg/ml) induced the morphology of blister formation or oncosis-blister cell death (BCD). Treatment of cells at an intermediate sanguinarine concentration (6.25 microg/ml) induced diffuse swelling or oncosis-diffuse cell swelling (DCS). To assess the underlying mechanism of sanguinarine-induced apoptosis and oncosis-BCD in K562 cells, we studied their response to pre-treatment with two chemical compounds: aurintricarboxylic acid (ATA) and cycloheximide (CHX). The pretreatment effects of both chemical compounds on apoptosis and oncosis-BCD were evaluated by measuring multiple parameters using quantitative morphology, electron microscopy, terminal deoxynucleotidyl transferase (TdT) end-labeling and annexin-V-binding. ATA, a DNA endonuclease inhibitor, efficiently prevented DNA nicking and inhibited apoptosis almost completely and oncosis-BCD by about 40%, while CHX, a protein synthesis inhibitor, failed to inhibit both apoptosis and oncosis-BCD. These results demonstrate, first, the importance of endonuclease in sanguinarine-induced apoptosis and to some extent in oncosis-BCD and, second, that this inhibition does not require de novo protein synthesis.

Serum-resistant lipopolyplexes for gene delivery to liver tumour cells.

In this study, an efficient non-viral gene transfer system has been developed by employing polyethylenimine (PEI 800, 25 and 22kDa) and DOTAP and cholesterol (Chol) as lipids (lipopolyplex), at three different lipid/DNA molar ratios (2/1, 5/1 and 17/1) by using five different protocols of formulation. Condensation assays revealed that PEI of 800, 25 and 22kDa were very effective in condensing plasmid DNA, leading to a complete condensation at N/P ratios above 4. Addition of DOTAP/Chol liposomes did not further condense DNA. Increasing the molar ratio lipid/DNA in the complex resulted in higher positive values of the zeta-potential, while the particle size increased in some protocols, but not in others. High molecular weight PEI (800kDa) used in the formulation of lipopolyplexes lead to a bigger particle size, compared to that obtained with smaller PEI species, whether branched (25kDa) or linear (22kDa). These vectors were also highly effective in protecting DNA from attack by DNAse I. Transfection activity was maximal by using protocols 3 and 4 and a lipid/DNA molar ratio of 17/1. These complexes showed high efficiency in gene delivery of DNA to liver cancer cells, even in the presence of high concentration of serum (60% FBS). On the other hand, complexes formed with linear PEI (22kDa) were more effective than lipopolyplexes containing branched PEI (800 or 25kDa). The complexes resulted to be much more efficient than conventional lipoplexes (cationic lipid and DNA) and polyplexes (cationic polymer and DNA). The same behaviour was observed for complexes prepared in the presence of the therapeutic gene pCMVIL-12. Toxicity assays revealed a viability higher than 80% in all cases, independently of the protocol, molar ratio (lipid/DNA), molecular weight and type of PEI.

Oral gene delivery: Strategies to improve stability of pDNA towards intestinal digestion.

PURPOSE: Gastrointestinal (GI) nucleases are responsible for a rapid presystemic degradation of orally administered transgenes. Within the current study, the activity of these degrading enzymes as well as the effect of various nuclease inhibitors on the degradation process were evaluated in order to assess their potential as auxiliary agents in oral gene delivery. METHODS: Digestion assays of pDNA with DNaseI and in GI juices were performed in absence and presence of inhibitors. Consequently, a chitosan conjugate with covalently bound ethylendiaminetetraacetic acid disodium salt dihydrat (EDTA) was synthesized and its nuclease inhibitory properties were evaluated. RESULTS: Small intestinal juice was shown to possess a nuclease activity per millilitre corresponding to 0.02 Kunitz units of DNaseI. Inhibition studies revealed that inhibitory activity followed the ranking: EDTA > sodium dodecyl sulfate (SDS) > aurintricarboxylic acid (ATA) > poly (acrylic acid) > cysteine. The chitosan-EDTA conjugate offered good nuclease inhibiting properties. CONCLUSION: This study determined the nuclease activity of native porcine small intestinal juice as well as enterocytes homogenate. Moreover, several promising strategies to overcome this enzymatic barrier were identified.

Soluble expression and characterization of a GFP-fused pea actin isoform (PEAc1).

A pea actin isoform PEAc1 with green fluorescent protein (GFP) fusion to its C-terminus and His-tag to its N-terminus, was expressed in prokaryotic cells in soluble form, and highly purified with Ni-Chelating Sepharose Fast Flow column. The purified fusion protein (PEAc1-GFP) efficiently inhibited DNase I activities before polymerization, and activated the myosin Mg-ATPase activities after polymerization. The PEAc1-GFP also polymerized into green fluorescent filamentous structures with a critical concentration of 0.75 uM. These filamentous structures were labeled by TRITC-phalloidin, a specific agent for staining actin microfilaments, and identified as having 9 nm diameters by negative staining. These results indicated that PEAc1 preserved the essential characteristics of actin even with His-tag and GFP fusion, suggesting a promising potential to use GFP fusion protein in obtaining soluble plant actin isoform to analyze its physical and biochemical properties in vitro. The PEAc1-GFP was also expressed in tobacco BY2 cells, which offers a new pathway for further studying its distribution and function in vivo.

Poly(ethylene glycol)-block-poly(L-lysine) dendrimer: novel linear polymer/dendrimer block copolymer forming a spherical water-soluble polyionic complex with DNA.

Methoxypoly(ethylene glycol)-block-poly(L-lysine) dendrimer was designed to form a water-soluble complex with plasmid DNA. The copolymer was synthesized by the liquid-phase peptide synthesis method. It was characterized by 1H NMR and matrix-assisted laser desorption ionization-time-of-flight (MALDI-TOF) mass spectrum. Agarose gel electrophoresis and DNase I protection assay proved that this linear polymer/dendrimer block copolymer assembled spontaneously with plasmid DNA, forming a water-soluble complex which increased the stability of the complexed DNA. Atomic force microscopy of the complex was evaluated at various charge ratios showing that the copolymer/DNA complex was like a globular shape.

Comparison of two methods of staining apoptotic cells of leukemia cell lines. Terminal deoxynucleotidyl transferase and DNA polymerase I reactions.

We compared two methods to stain apoptotic cells, one using terminal deoxynucleotidyl transferase (TDT), the other DNA polymerase I, using leukemia cell lines treated with anti-Fas monoclonal antibody (MAb). Both TDT and polymerase I strongly reacted with fragmented nuclei of apoptotic MOLT-16 and Jurkat cells, but only polymerase I strongly reacted with nonfragmented nuclei of early apoptotic cells. Anti-Fas MAb-treated MOLT-4 cells showed morphological changes corresponding to early apoptosis and were strongly positive for polymerase I only. MOLT-16 and Jurkat cells treated with anti-Fas MAb and inhibitors of endonuclease and poly(ADP-ribose) polymerase showed the morphology of early apoptosis but were not strongly stained by TDT. Because DNA polymerase I has nick-translation activity, it is possible that DNA polymerase I reaction is positive in early apoptotic cells by detecting single-strand DNA cleavage, which occurs before extensive oligonucleosomal DNA cleavage and late morphological changes of apoptosis in leukemia cell lines. Although TDT is widely used to stain apoptotic cells, DNA polymerase I may be more applicable in special cases of apoptosis, in which cells undergo single-strand rather than double-strand DNA breaks. However, the procedure has limitations, such as the necessity to use cell smears for comparison with the TDT reaction. (J Histochem Cytochem 46:85-90, 1998)

Measurement of deoxyribonuclease I (DNase) in the serum and urine of systemic lupus erythematosus (SLE)-prone NZB/NZW mice by a new radial enzyme diffusion assay.

A new radial enzyme diffusion (RED) method for the measurement of DNase activity in serum and urine is described. The sensitivity of the assay is in the range of 15.6-500 ng/ml. The assay is based on the hydrolysis of double-stranded (ds) DNA (or nucleosomes) in agarose. The specificity of the reaction for DNase I was established by showing that either EDTA in the reaction buffer or G-actin abolished DNase activity. Being a functional assay, RED has advantages over radioimmunoassay (RIA) or ELISA, since antigenic assays may also measure complexes of DNase with actin. This method was used to measure DNase activity in the sera and urine of lupus-prone mice (NZB/NZW F1 hybrids, aged 4-6 weeks). Serum DNase activity in these mice was significantly lower (mean 9 ng/ml) than in control, normal mice of the same age and sex (mean 37 ng/ml). Concentration of DNase in the urine of 4-6-week-old female NZB/NZW F1 hybrids (24 ng/ml) was significantly lower then in control mice (521 ng/ml). The RED method was used to measure the concentration of actin as the DNase inhibitor in serum. G-actin in the presence of ATP binds DNase and inhibits its nucleolytic activity. Since ATP is necessary for the actin inhibition of DNase I, this shows that there is actin as well as DNase I in the serum. Actin is not only ATP-dependent, but also heat-labile. Heating the sera for 10 min at 50 degrees C increases DNase activity. This is an alternative method for measuring the concentration of actin in the serum. An almost identical estimate of actin concentration in sera of normal mice was found from the difference of DNase activity in the presence or absence of ATP (mean actin concentration = 21 ng/ml) or from the difference of DNase activity in heated and non-heated serum (mean actin concentration 18 ng/ml). We were not able to demonstrate DNase inhibitors in the urine of either control or NZB/W F1 hybrid mice.

Identification of actin as an estradiol 17-beta-stimulated protein in the human placenta.

Addition of estradiol 17-beta to first trimester human placental minces resulted in an increased synthesis of a protein of apparent molecular weight 45 kDa. The specific involvement of estrogen in the stimulation of this protein was established by demonstrating a reduction in the level of this protein by the addition of CGS 16949 A, an inhibitor of aromatase, a key enzyme in the biosynthesis of estradiol 17-beta and ICI 182,780, an estrogen receptor antagonist. The protein was purified to homogeneity and N-terminal sequencing of two of the internal peptides obtained by enzymatic digestion of the protein, as well as the absence of a free N-terminal indicated that it could be actin. This was confirmed by Western blotting using commercially available actin antiserum. The role of estradiol 17-beta in the stimulation of actin synthesis in human placenta was also established by monitoring the quantitative inhibition of DNase I by actin.

Induction of HSP70 gene expression by modulation of Ca(+2) ion and cellular p53 protein by curcumin in colorectal carcinoma cells.

Curcumin (diferuloyl methane) is the major active yellow pigment of turmeric and curry. Studies in recent years have indicated that curcumin is a potent inhibitor of the initiation and promotion of chemical carcinogen-induced skin carcinogenesis in mice. When COLO205 colorectal carcinoma cells were treated with curcumin (60 microM), the appearance of apoptotic DNA ladders was delayed about 5 h, and G1 arrest was detected. Further analysis of the endonuclease activities in these cells revealed that the activity of Ca(+2)-dependent endonuclease in COLO205 cells was profoundly inhibited and that the extent of inhibition depended on the degree of calcium depletion. The reduction of p53 gene expression was accompanied by the induction of HSP70 gene expression in the curcumin-treated cells. These findings suggest that curcumin may induce the expression of the HSP70 gene through the initial depletion of intracellular Ca(+2), followed by the suppression of p53 gene function in the target cells.

Engineering actin-resistant human DNase I for treatment of cystic fibrosis.

Human deoxyribonuclease I (DNase I), an enzyme recently approved for treatment of cystic fibrosis (CF), has been engineered to create two classes of mutants: actin-resistant variants, which still catalyze DNA hydrolysis but are no longer inhibited by globular actin (G-actin) and active site variants, which no longer catalyze DNA hydrolysis but still bind G-actin. Actin-resistant variants with the least affinity for actin, as measured by an actin binding ELISA and actin inhibition of [33P] DNA hydrolysis, resulted from the introduction of charged, aliphatic, or aromatic residues at Ala-114 or charged residues on the central hydrophobic actin binding interface at Tyr-65 or Val-67. In CF sputum, the actin-resistant variants D53R, Y65A, Y65R, or V67K were 10-to 50-fold more potent than wild type in reducing viscoelasticity as determined in sputum compaction assays. The reduced viscoelasticity correlated with reduced DNA length as measured by pulsed-field gel electrophoresis. In contrast, the active site variants H252A or H134A had no effect on altering either viscoelasticity or DNA length in CF sputum. The data from both the active site and actin-resistant variants demonstrate that the reduction of viscoelasticity by DNase I results from DNA hydrolysis and not from depolymerization of filamentous actin (F-actin). The increased potency of the actin-resistant variants indicates that G-actin is a significant inhibitor of DNase I in CF sputum. These results further suggest that actin-resistant DNase I variants may have improved efficacy in CF patients.

O6-alkylguanine-DNA alkyltransferase, DNase I, nucleic acid synthesis and nucleoids in vitro under the influence of pentosan polysulfate.

The in vitro influence of pentosan polysulfate (CAS 116001-96-8, PPS) on DNase I activity as well as on O6-alkylguanine-DNA alkyltransferase (AT), nucleic acid synthesis, nucleoid sedimentation and viscosity of alkaline lysates of chicken embryo brain cells was studied. PPS inhibited the activities of AT and DNase I in a dose-dependent manner, with ED50 values being about 13 and 380 micrograms/ml. Scheduled DNA synthesis was depleted by PPS. The ED50 values ranged between 45 and 55 micrograms PPS/ml. A slight increase in RNA synthesis could be observed at polyanion concentrations of 28-112 micrograms/ml. Nucleoid sedimentation and viscosity of alkaline cell lysates reflected a decrease in chromatin compactness at lower (7-25 micrograms/ml) and an increase in chromatin compactness at higher (> or approximately = 112 micrograms/ml) PPS concentrations. From the present results it is concluded that PPS, at clinically relevant concentrations, is able to interact in vitro with enzyme systems being critical to important nuclear functions. The remarkably high sensitivity of the nuclear enzyme AT deserves further investigations with regard to a possible synergism of polyanions and chemotherapeutically used alkylating agents.

Interaction of macrolides with alpha dornase during DNA hydrolysis.

Since patients with cystic fibrosis are often treated with alpha dornase to reduce sputum viscosity, and because of preliminary reports of efficacy of long-term low-dose erythromycin therapy in chronic airway diseases, it is likely that alpha dornase and macrolides might be given together in such patients. A possible interaction between these drugs was therefore investigated. Using hyperchromic effect to quantify alpha dornase activity, a time- and dose-dependent inhibitory effect on human DNA hydrolysis has been observed for erythromycin, roxithromycin and azithromycin. Inhibitory doses 50% for alpha dornase were graphically determined. Azithromycin exhibited the strongest inhibitory effect.