Why ribonucleases cause death of cancer cells

Molecular properties and possible mechanisms of action of cytotoxic ribonucleases (RNases), potential antitumor therapeutics, are characterized. The analysis of recent publications and own experimental results have allowed the authors, on the one hand, to distinguish cellular components that are responsible for selective activity of exogenous RNases towards malignant cells, and on the other--to identify the contribution of definite molecular determinants to the enzyme cytotoxicity. The predominant effect of the RNase molecule charge on the cell death induction is shown. The RNase cytotoxic effects are caused by catalytic cleavage of available RNA, by products of its hydrolysis, as well as by non-catalytic electrostatic interaction of exogenous enzyme with cell components. Potential targets for RNase action in a cancer cell have been revealed. The role of modulation of the membrane calcium-dependent potassium channels and ras-oncogene functions in the RNase-induced cell damage is defined. The effect of cytotoxic RNases on gene expression via influencing the RNA interference is discussed.     

Endowing human pancreatic ribonuclease with toxicity for cancer cells

Onconase is an amphibian protein that is now in Phase III clinical trials as a cancer chemotherapeutic. Human pancreatic ribonuclease (RNase 1) is homologous to Onconase but is not cytotoxic. Here, ERDD RNase 1, which is the L86E/N88R/G89D/R91D variant of RNase 1, is shown to have conformational stability and ribonucleolytic activity similar to that of the wild-type enzyme but > 10(3)-fold less affinity for the endogenous cytosolic ribonuclease inhibitor protein. Most significantly, ERDD RNase 1 is toxic to human leukemia cells. The addition of a non-native disulfide bond to ERDD RNase 1 not only increases the conformational stability of the enzyme but also increases its cytotoxicity such that its IC(50) value is only 8-fold greater than that of Onconase. Thus, only a few amino acid substitutions are necessary to make a human protein toxic to human cancer cells. This finding has significant implications for human cancer chemotherapy.     

Design and synthesis of metal-free artificial ribonucleases

The present review is aimed at giving a general overview of our results in the field of designing and synthesizing simple peptide-like molecules that mimic structural and functional aspects of natural ribonucleases, as well as designing oligonucleotide-based artificial ribonucleases.     

Molecular mechanism of therapeutic approaches for human gastric cancer stem cells

Gastric cancer(GC)is a primary cause of cancer-related mortality worldwide,and even after therapeutic gastrectomy,survival rates remain poor.The presence of gastric cancer stem cells(GCSCs)is thought to be the major reason for resistance to anticancer treatment(chemotherapy or radiotherapy),and for the development of tumor recurrence,epithelial–mesenchymal transition,and metastases.Additionally,GCSCs have the capacity for self-renewal,differentiation,and tumor initiation.They also synthesize antiapoptotic factors,demonstrate higher performance of drug efflux pumps,and display cell plasticity abilities.Moreover,the tumor microenvironment(TME;tumor niche)that surrounds GCSCs contains secreted growth factors and supports angiogenesis and is thus responsible for the maintenance of the growing tumor.However,the genesis of GCSCs is unclear and exploration of the source of GCSCs is essential.In this review,we provide up-todate information about GCSC-surface/intracellular markers and GCSC-mediated pathways and their role in tumor development.This information will support improved diagnosis,novel therapeutic approaches,and better prognosis using GCSC-targeting agents as a potentially effective treatment choice following surgical resection or in combination with chemotherapy and radiotherapy.To date,most anti-GCSC blockers when used alone have been reported as unsatisfactory anticancer agents.However,when used in combination with adjuvant therapy,treatment can improve.By providing insights into the molecular mechanisms of GCSCs associated with tumors in GC,the aim is to optimize anti-GCSCs molecular approaches for GC therapy in combination with chemotherapy,radiotherapy,or other adjuvant treatment.     

Molecular design of artificial ribonucleases using electrostatic interaction

A number of small organic ribonucleases have been synthesized with rigid polycationic structures containing an aromatic framework with two residues of bis-quaternary salts of 1,4-diazabicyclo[2.2.2]octane (DABCO) bearing various substituents. The compounds carrying positively charged groups connected via rigid linker are expected to bend the sugar-phosphate backbone and can stimulate the intramolecular phosphoester transfer reaction.     

Inhibition of the human thioredoxin system. A molecular mechanism of mercury toxicity

Mercury toxicity mediated by different forms of mercury is a major health problem; however, the molecular mechanisms underlying toxicity remain elusive. We analyzed the effects of mercuric chloride (HgCl(2)) and monomethylmercury (MeHg) on the proteins of the mammalian thioredoxin system, thioredoxin reductase (TrxR) and thioredoxin (Trx), and of the glutaredoxin system, glutathione reductase (GR) and glutaredoxin (Grx). HgCl(2) and MeHg inhibited recombinant rat TrxR with IC(50) values of 7.2 and 19.7 nm, respectively. Fully reduced human Trx1 bound mercury and lost all five free thiols and activity after incubation with HgCl(2) or MeHg, but only HgCl(2) generated dimers. Mass spectra analysis demonstrated binding of 2.5 mol of Hg(2+) and 5 mol of MeHg(+)/mol of Trx1 with the very strong Hg(2+) complexes involving active site and structural disulfides. Inhibition of both TrxR and Trx activity was observed in HeLa and HEK 293 cells treated with HgCl(2) or MeHg. GR was inhibited by HgCl(2) and MeHg in vitro, but no decrease in GR activity was detected in cell extracts treated with mercurials. Human Grx1 showed similar reactivity as Trx1 with both mercurial compounds, with the loss of all free thiols and Grx dimerization in the presence of HgCl(2), but no inhibition of Grx activity was observed in lysates of HeLa cells exposed to mercury. Overall, mercury inhibition was selective toward the thioredoxin system. In particular, the remarkable potency of the mercury compounds to bind to the selenol-thiol in the active site of TrxR should be a major molecular mechanism of mercury toxicity.     

水飞蓟宾抑制人肺癌细胞浸润的作用机制研究

目的通过观察水飞蓟宾对有高转移能力的人肺癌细胞A549相关酶的作用来研究水飞蓟宾对浸润和运动性的影响。方法应用细胞活性测定、细胞浸润和运动性分析、细胞-基质黏附实验、逆转录聚合酶链反应等技术完成实验。结果A549细胞用高达100μM的不同浓度的水飞蓟宾处理一定时间后,行明胶酶谱、酪蛋白酶谱以及蛋白印迹分析来确定水飞蓟宾对金属蛋白酶-2（MMP-2）的影响。结论水飞蓟宾治疗可以浓度以及时间依存性方式减少MMP-2表达。半定量RT—PCR分析进一步表明,水飞蓟宾可在转录水平调节MMP-2表达。     

A division-linked mechanism for the rapid generation of Ig-secreting cells from human memory B cells

Memory B cells, when re-exposed to Ag and T cell help, differentiate into Ig-secreting cells (ISC) at the same time as maintaining a residual pool of non-Ig-secreting cells with memory capabilities. To investigate the mechanism underlying this dual process, we followed the fate of human B cells activated in vitro with the T cell-derived signals CD40 ligand (CD40L), IL-2, and IL-10 using CFSE to monitor cell division. A substantial number of ISCs detected by ELISPOT, intracellular Ig staining, and Ig secretion could be generated from memory but not naive B cells. The proportion of ISCs increased with successive cell divisions and was markedly enhanced by IL-10 at each division. Within ISCs, two distinct populations were detected after withdrawal of CD40L. The first had acquired the plasma cell marker CD38 and continued to proliferate despite the absence of CD40L. In contrast, the second population remained CD38(-), ceased dividing, and underwent rapid apoptosis. The former most likely represent the immediate precursors of long-lived plasma cells, which preferentially home to the bone marrow in vivo, whereas the latter contain short-lived ISCs responsible for the initial Ab response to stimulation with Ag and T cell help. Taken together, the results point to a division-based mechanism responsible not only for regulating differentiation of short- and long-lived ISCs from memory B cells, but for preserving the memory B cell pool for reactivation upon subsequent Ag exposure.     

植物提取十八碳二烯酸对人胃癌组织细胞生态毒理学作用机制研究

为了探索植物提取十八碳二烯酸对人胃癌组织细胞生态毒理学作用机制,取胃癌患者肿瘤组织移植到重症联合免疫缺陷(SCID)小鼠皮下,腹腔注射100、300、900 mg·kg-1植物提取物十八碳二烯酸,分析对移植瘤生长抑制作用;用酶联免疫吸附法(ELISA)检测瘤组织cAMP、P53、PI3K水平.将瘤组织经酶解消化分离出细...     

Selective toxicity of dihydroartemisinin and holotransferrin toward human breast cancer cells.

Artemisinin becomes cytotoxic in the presence of ferrous iron. Since iron influx is high in cancer cells, artemisinin and its analogs selectively kill cancer cells under conditions that increase intracellular iron concentrations. We report here that after incubation with holotransferrin, which increases the concentration of ferrous iron in cancer cells, dihydroartemisinin, an analog of artemisinin, effectively killed a type of radiation-resistant human breast cancer cell in vitro. The same treatment had considerably less effect on normal human breast cells. Since it is relatively easy to increase the iron content inside cancer cells in vivo, administration of artemisinin-like drugs and intracellular iron-enhancing compounds may be a simple, effective, and economical treatment for cancer.     

An RNA sequence determines the speed of its cleavage by artificial ribonucleases

Phosphodiester bonds in RNA situated between similar nucleotides but in different sequences (context) were cleaved under the action of artificial and natural ribonucleases with different speeds, and the reason for this phenomenon has not yet been fully revealed. In this study, the influence of one-nucleotide substitution on the sensitivity to cleavage of the phosphodiester bonds in linear and structured RNA with homologous sequences is studied for the first time. It is indicated that the introduction of one-nucleotide substitution in the RNA sequence significantly (up to 10 times) changes the speed of the cleavage of the bonds that are separated from the substitution point not only by 1–3, but also 6–8 nucleotides, by artificial ribonucleases. The observed regularities may be explained by the fact that the introduction of a one-nucleotide substitution significantly changes the stacking interactions and the net of hydrogen bonds in the RNA molecule. The applied value of this study consists of the ability of using low-molecular artificial ribonucleases with the aim of choosing the region of the binding of the oligonucleotide in the construction of a conjugate for the site-directed cutting of RNA, because the choice of a phosphodiester bond (motif) easily subjected to cleavage significantly determines the efficacy of artificial ribonucleases of directed action.     

A mechanism for acute aluminium toxicity in fish

Aluminium is acutely toxic to fish in acid waters. The gill is the principal target organ and death is due to a combination of ionoregulatory, osmoregulatory and respiratory dysfunction. The toxic mechanism has hitherto received little direct consideration and is unknown. In this paper the mechanism of acute aluminium toxicity is approached from a chemical perspective. Symptomatic evidence of toxicity is taken from the literature and combined with our own research to elucidate a biochemically sound model to describe a possible mechanism of acute aluminium toxicity in fish. The proposed model delineates the chemical conditions immediately adjacent to the gill surface and emphasizes their importance in aluminium's toxic mode of action. The mechanism is shown to be bipartite. Aluminium binding to functional groups both apically located at the gill surface and intracellularly located within lamellar epithelial cells disrupts the barrier properties of the gill epithelium. The concomitant iono- and osmoregulatory dysfunction results in accelerated cell necrosis, sloughing and death of the fish. The mechanism of epithelial cell death is proposed as a general mechanism of aluminium-induced accelerated cell death.     

Thioredoxin reductase 1 deficiency enhances selenite toxicity in cancer cells via a thioredoxin-independent mechanism

Selenium is an essential trace element in mammals, but is toxic at high levels. It is best known for its cancer prevention activity, but cancer cells are more sensitive to selenite toxicity than normal cells. Since selenite treatment leads to oxidative stress, and the Trx (thioredoxin) system is a major antioxidative system, we examined the interplay between TR1 (Trx reductase 1) and Trx1 deficiencies and selenite toxicity in DT cells, a malignant mouse cell line, and the corresponding parental NIH 3T3 cells. TR1-deficient cells were far more sensitive to selenite toxicity than Trx1-deficient or control cells. In contrast, this effect was not seen in cells treated with hydrogen peroxide, suggesting that the increased sensitivity of TR1 deficiency to selenite was not due to oxidative stress caused by this compound. Further analyses revealed that only TR1-deficient cells manifested strongly enhanced production and secretion of glutathione, which was associated with increased sensitivity of the cells to selenite. The results suggest a new role for TR1?in cancer that is independent of Trx reduction and compensated for by the glutathione system. The results also suggest that the enhanced selenite toxicity of cancer cells and simultaneous inhibition of TR1 can provide a new avenue for cancer therapy.     

Towards artificial ribonucleases: the sequence-specific cleavage of RNA in a duplex.

Lanthanide complexes covalently attached to oligonucleotides have been shown to cleave RNA in a sequence-specific manner. Efficient cleavage, however, is at present limited to single-stranded RNA regions, as RNA in a duplex is considerably more resistant to strand scission. To overcome this limitation, we have designed and synthesised artificial nucleases comprising lanthanide complexes covalently linked to oligodeoxyribonucleotides which cleave a partially complementary RNA at a bulged site, in the duplex region. Strand scission occurs at or near the bulge. Cleavage of the RNA target by the metal complex can be addressed via the major or the minor groove. In an example of a competitive situation, where the cleavage moiety has access to both a bulge and a single-strand region, transesterification at the bulge is favoured. Such artificial ribonucleases may find application as antisense agents and as tools in molecular biology. In addition, the results may have importance for the design of artificial ribonucleases which are able to act with catalytic turnover.     

Adenosine uptake is the major effector of extracellular ATP toxicity in human cervical cancer cells

In cervical cancer, HPV infection and disruption of mechanisms involving cell growth, differentiation, and apoptosis are strictly linked with tumor progression and invasion. Tumor microenvironment is ATP and adenosine rich, suggesting a role for purinergic signaling in cancer cell growth and death. Here we investigate the effect of extracellular ATP on human cervical cancer cells. We find that extracellular ATP itself has a small cytotoxic effect, whereas adenosine formed from ATP degradation by ectonucleotidases is the main factor responsible for apoptosis induction. The level of P2×7 receptor seemed to define the main cytotoxic mechanism triggered by ATP, since ATP itself eliminated a small subpopulation of cells that express high P2×7 levels, probably through its activation. Corroborating these data, blockage or knockdown of P2×7 only slightly reduced ATP cytotoxicity. On the other hand, cell viability was almost totally recovered with dipyridamole, an adenosine transporter inhibitor. Moreover, ATP-induced apoptosis and signaling—p53 increase, AMPK activation, and PARP cleavage—as well as autophagy induction were also inhibited by dipyridamole. In addition, inhibition of adenosine conversion into AMP also blocked cell death, indicating that metabolization of intracellular adenosine originating from extracellular ATP is responsible for the main effects of the latter in human cervical cancer cells.     

Purification and characterization of three ribonucleases from human kidney: comparison with urine ribonucleases

Three ribonucleases (RNases) with different molecular masses were isolated from human kidney. The enzymes were purified to an electrophoretically homogeneous state, and their respective molecular masses were found to be 18,000 (tentatively named RNase HK-1), 20,000 (RNase HK-2A), and 22,000 (RNase HK-2B) on sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Analysis of the amino acid compositions, amino-terminal sequences, and enzymological properties of the enzymes indicate that RNase HK-1 is related to "nonsecretory" RNase, and that RNases HK-2A and HK-2B are both related to "secretory" RNase. Furthermore, RNase HK-1 showed cross-reactivity with an antibody specific to nonsecretory RNase from human urine, whereas RNases HK-2A and HK-2B showed cross-reactivity with another antibody specific to human urine secretory RNase. However, the carbohydrate compositions of RNases HK-2A and HK-2B were markedly different from that of the secretory urine RNase. This finding seems to indicate that the kidney is not the origin of the urine enzyme.