Polymorphisms in the methylenetetrahydrofolate reductase gene: clinical consequences

5,10-Methylenetetrahydrofolate reductase (MTHFR) plays a key role in folate metabolism by channeling one-carbon units between nucleotide synthesis and methylation reactions. Severe enzyme deficiency leads to hyperhomocysteinemia and homocystinuria, with altered folate distribution and a phenotype that is characterized by damage to the nervous and vascular systems. Two frequent polymorphisms in the human MTHFR gene confer moderate functional impairment of MTHFR activity for homozygous mutant individuals. The C to T change at nucleotide position 677, whose functional consequences are dependent on folate status, has been extensively studied for its clinical consequences. A second polymorphism, an A to C change at nucleotide position 1298, is not as well characterized. Still equivocal are associations between MTHFR polymorphisms and vascular arteriosclerotic or thrombotic disease. Neural tube defects and pregnancy complications appear to be linked to impaired MTHFR function. Colonic cancer and acute leukemia, however, appear to be less frequent in individuals homozygous for the 677T polymorphism.MTHFR polymorphisms influence the homocysteine-lowering effect of folates and could modify the pharmacodynamics of antifolates and many other drugs whose metabolism, biochemical effects, or target structures require methylation reactions. However, only preliminary evidence exists for gene-drug interactions. This review summarizes the biochemical basis and clinical evidence for interactions between MTHFR polymorphisms and several disease entities, as well as potential interactions with drug therapies. Future investigations of MTHFR in disease should consider the influence of other variants of functionally-related genes as well as the medication regimen of the patients. Animal models for genetic deficiencies in folate metabolism will likely play a greater role in our understanding of folate-dependent disorders.     

The metabolic basis of deoxyuridine cytotoxicity. Studies of cultured human lymphoblasts

The metabolic consequences of deoxyuridine treatment in four cultured human lymphoblast lines (CCRF-CEM, RPMI-8402, JM, and BALM) were studied by cell growth experiments, flow cytometry, and measurement of 2'-deoxyribonucleoside triphosphate (dNTP) levels. DNA perturbations occurred in all lymphoblast lines, but there was no significant impairment of RNA synthesis. The DNA perturbations in CCRF-CEM, RPMI-8402, and BALM cells reflected inhibition of DNA synthesis, and the associated dNTP changes were consistent with ribonucleotide reductase inhibition or, specifically in BALM cells, with DNA alpha-polymerase inhibition. JM cells treated with an intermediate concentration of deoxyuridine developed a block at the G1/S boundary which was deoxyuridine concentration-dependent, but not specific for deoxyuridine (it was also seen with thymidine treatment) and not related to DNA synthesis inhibition. There were no idiosyncratic dNTP effects accompanying the G1/S boundary block, and the responsible metabolic mechanism remains to be determined.     

Folate and homocysteine metabolism: therapeutic targets in cardiovascular and neurodegenerative disorders

Individuals with elevated homocysteine levels are at increased risk for cardiovascular disease and stroke, and neurodegenerative disorders such as Alzheimer's and Parkinson's diseases Homocysteine is a modified form of the amino acid methionine that is tightly regulated by enzymes requiring folate. By impairing DNA repair mechanisms and inducing oxidative stress, homocysteine can cause the dysfunction or death of cells in the cardiovascular and nervous systems. Dietary folate stimulates homocysteine removal and may thereby protect cells against disease processes. The enzymes involved in homocysteine and folate metabolism provide novel targets for drug discovery.     

育龄妇女叶酸代谢相关基因多态性分布研究

目的 了解育龄妇女叶酸代谢相关基因多态性的分布状况,利用基因检测技术筛查出叶酸利用能力差的高风险人群,为育龄妇女提供科学合理的叶酸补充方案.方法 选取144例育龄妇女作为研究对象,通过DNA提取、PCR扩增、PCR产物基因测序等分子生物学技术对亚甲基四氢叶酸还原酶(MTHFR)和甲硫氨酸合成酶还原酶(MTRR)等叶酸代谢相关基因进行单核苷酸多态性(Single Nucleotide Polymorphisms,SNP)位点的检测.结果 MTHFR677位点CC、CT、TT基因型频率分别为21.5%、40.3%、38.2%;MTHFR 1298位点AA、AC、CC基因型的频率分别为75.0%、22.2%、2.8%;MTRR66位点AA、AG、GG基因型频率分别为63.2%、31.3%、5.6%.结论 通过对MTHFR基因和MTRR基因相关位点的检测,可筛查出叶酸利用能力差的高风险人群,为其合理增补叶酸提供科学依据.     

Altered expression of methylenetetrahydrofolate reductase modifies response to methotrexate in mice

OBJECTIVE: Folates provide one-carbon units for nucleotide synthesis and methylation reactions. A common polymorphism (677C-->T) in methylenetetrahydrofolate reductase (MTHFR) encodes an enzyme with reduced activity. Response to the antifolate methotrexate (MTX) may be modified in 677TT individuals because MTHFR converts nonmethylated folates, used for thymidine and purine synthesis, to 5-methyltetrahydrofolate, used in homocysteine remethylation to methionine. To study potential interactions between MTHFR activity and MTX, we examined the impact of decreased and increased MTHFR expression on MTX response in mice. METHODS: Mthfr-deficient (Mthfr and Mthfr) and wild-type (Mthfr) mice were injected with MTX or saline and assessed for hematological parameters (hematocrit, hemoglobin, red, and white blood cell numbers), plasma homocysteine, nephrotoxicity, hepatotoxicity, and splenic 2'-deoxyuridine 5'-triphosphate/2'-deoxythymidine 5'-triphosphate ratios. MTHFR-overexpressing transgenic mice (MTHFR-Tg) were generated, metabolites and folate distributions were measured, and response to MTX was assessed. RESULTS: MTX-treated Mthfr and Mthfr mice displayed hyperhomocysteinemia and decreased hematocrit, hemoglobin, and red blood cell numbers compared with wild-type animals. Mthfr mice also showed increased nephrotoxicity and hepatotoxicity. MTHFR-Tg mice were generated and confirmed to have increased levels of MTHFR with altered distributions of folate and thiols in a tissue-specific manner. After MTX treatment, MTHFR-Tg mice exhibited the same decreases in hematological parameters as Mthfr-deficient mice, and significantly decreased thymidine synthesis (higher 2'-deoxyuridine 5'-triphosphate/2'-deoxythymidine 5'-triphosphate ratios) compared with wild-type mice, but they were protected from MTX-induced hyperhomocysteinemia. CONCLUSION: Underexpression and overexpression of Mthfr/MTHFR increase MTX-induced myelosuppression but have distinct effects on plasma homocysteine and nephrotoxicity. Pharmacogenetic analysis of polymorphisms in folate-dependent enzymes may be useful in optimization of MTX therapy.     

Uracil in DNA: consequences for carcinogenesis and chemotherapy

The synthesis of thymidylate (TMP) occupies a convergence of two critical metabolic pathways: folate metabolism and pyrimidine biosynthesis. Thymidylate is formed from deoxyuridylate (dUMP) using N(5),N(10)-methylene tetrahydrofolate. The metabolic relationship between dUMP, TMP, and folate has been the subject of cancer research from prevention to chemotherapy. Thymidylate stress is induced by nutritional deficiency of folic acid, defects in folate metabolism, and by antifolate and fluoropyrimidine chemotherapeutics. Both classes of chemotherapeutics remain mainstay treatments against solid tumors. Because of the close relationship between dUMP and TMP, thymidylate stress is associated with increased incorporation of uracil into DNA. Genomic uracil is removed by uracil DNA glycosylases of base excision repair (BER). Unfortunately, BER is apparently problematic during thymidylate stress. Because BER requires a DNA resynthesis step, elevated dUTP causes reintroduction of genomic uracil. BER strand break intermediates are clastogenic if not repaired. Thus, BER during thymidylate stress appears to cause genome instability, yet might also contribute to the mechanism of action for antifolates and fluoropyrimidines. However, the precise roles of BER and its components during thymidylate stress remain unclear. In particular, links between BER and downstream events remain poorly defined, including damage signaling pathways and homologous recombination (HR). Evidence is growing that HR responds to persistent BER strand break intermediates and DNA damage signaling pathways mediate cross talk between BER and HR. Examination of crosstalk among BER, HR, and damage signaling may shed light on decades of investigation and provide insight for development of novel chemopreventive and chemotherapeutic approaches.     

Ligand binding and kinetics of folate receptor recycling in vivo: impact on receptor-mediated drug delivery

Folate receptor-targeted cancer therapies constitute a promising treatment for the approximately one third of human cancers that overexpress the folate receptor (FR). However, the potencies of all folate-receptor targeted therapies depend on 1) the rate of folate-linked drug conjugate binding to the cancer cell surface, 2) the dose of folate conjugate that will saturate tumor cell surface FR in vivo, 3) the rate of FR internalization, unloading, and recycling back to the tumor cell surface for another round of conjugate uptake, and 4) the residence time of the folate conjugate before its metabolism or release from the cell. Because little information exists on any of these processes, we have undertaken to characterize them on both cancer cells in culture and solid tumors in live mice. We quantitate here the properties of FR saturation, internalization, recycling, and unloading in several cultured cancer cell lines and murine tumor models, and we describe the conditions that should maximize both the potencies and specificities of folate receptor-targeted therapies in vivo.     

Anti-cancer drugs targeting fatty acid synthase (FAS)

Fatty acid synthase (FAS) is a key enzyme of the fatty acid biosynthetic pathway which catalyzes de novo lipid synthesis. FAS expression in normal adult tissues is generally very low or undetectable as majority of fatty acids obtained are from dietary sources, whereas it is significantly upregulated in cancer cells despite adequate nutritional lipid supply. Activation of FAS provides rapidly proliferating tumor cells sufficient amount of lipids for membrane biogenesis and confers growth and survival advantage possibly acting as a metabolic oncogene. Importantly, inhibition of FAS in cancer cells using the pharmacological FAS inhibitors results in tumor cell death by apoptosis whereas normal cells are resistant. Due to this differential expression of FAS, the inhibitors of this enzyme are selectively toxic to tumor cells and therefore FAS is considered an attractive therapeutic target for cancer. Several FAS inhibitors are already patented and commercially available; however, the potential toxicity of these FAS inhibitors remains to be tested in clinical trials. In this review, we discuss some of the potent FAS inhibitors along with their patent information, the mechanism of anti-cancer effects and the development of more specific and potent FAS inhibitors with lower side effects that are expected to emerge as anti-cancer treatment in the near future.     

Elevation of cysteine consumption in tamoxifen-resistant MCF-7 cells

Tamoxifen (TAM) resistance is a main cause of therapeutic failure in breast cancers. Although methionine dependency is a phenotypic characteristic of tumor cells, the role of sulfur amino acid metabolism in chemotherapy resistance remains to be elucidated. This study compared metabolite profiles of sulfur amino acid metabolism from methionine to taurine or glutathione (GSH) between normal MCF-7 and TAM-resistant MCF-7 (TAMR-MCF-7) cells. TAMR-MCF-7 cells showed elevated levels and activities of enzymes involved in both transsulfuration from methionine to cysteine and metabolism of cysteine to GSH and taurine. Cysteine concentrations in TAMR-MCF-7 cells and medium conditioned by cell culture for 42 h were markedly decreased, while GSH, hypotaurine, and taurine concentrations in the medium were increased. These results show that TAMR-MCF-7 cells display enhanced cysteine utilization. The addition of propargylglycine, a specific cystathionine γ-lyase inhibitor, and buthionine sulfoximine, a specific γ-glutamylcysteine ligase inhibitor, to TAMR-MCF-7 cells, but not to MCF-7 cells, resulted in cytotoxicity after sulfur amino acid deprivation. These results suggest that cell viability of TAMR-MCF-7 cells is affected by inhibition of sulfur amino acid metabolism, particularly cysteine synthesis from homocysteine and GSH synthesis from cysteine. Additionally, the S-adenosylmethionine/S-adenosylhomocysteine ratio, an index of transmethylation potential, in TAMR-MCF-7 cells increased to ～3.6-fold relative to that in MCF-7 cells, a finding that may result from upregulation of methionine adenosyltransferase IIa and S-adenosylhomocysteine hydrolase. In conclusion, this study suggests that TAMR-MCF-7 cells display enhanced cysteine utilization for synthesis of GSH and taurine, and are sensitive to inhibition of cysteine metabolism.     

Methylenetetrahydrofolate reductase (MTHFR) variants and fluorouracil-based treatments in colorectal cancer

5-fluorouracil (5FU)-based treatments remain the main chemotherapy for colorectal cancer. Optimal cytotoxicity of fluoropyrimidines requires elevated CH(2)FH(4) tumoral concentrations, controlled by the methylenetetrahydrofolate reductase (MTHFR) enzyme, which irreversibly converts CH(2)FH(4) into 5-methyltetrahydrofolate. The MTHFR gene is subject to several polymorphisms, of which the 677C>T and 1298A>C SNPs are the two most commonly linked with altered enzyme activity. Since a drop in MTHFR enzymatic activity may theoretically favor an increase in intracellular CH(2)FH(4) concentrations, it can be hypothesized that tumors exhibiting the rare MTHFR variants may be more sensitive to 5FU cytotoxicity. Accordingly, experimental data have shown that rare MTHFR variants in position 677 and 1298 are more sensitive to 5FU. However, results of clinical data do not concord regarding the influence of MTHFR genotype on tumoral CH(2)FH(4) concentration, 5FU responsiveness, patient survival and 5FU-related toxicity. These discrepancies may result from the interpatient variability arising from the individual folate status, as well as from the limited role of fluoropyrimidines in the current chemotherapy regimen administered in colorectal cancer.     

Recent advances in lamellarin alkaloids: isolation, synthesis and activity

Lamellarins are a large family of marine alkaloids with potential anticancer activity that have been isolated from diverse marine organisms, mainly ascidians and sponges. All lamellarins feature a 3,4-diarylpyrrole system. Pentacyclic lamellarins, whose polyheterocyclic system has a pyrrole core, are the most active compounds. Some of these alkaloids are potently cytotoxic to various tumor cell lines. To date, Lam-D and Lam-H have been identified as lead compounds for the inhibition of topoisomerase I and HIV-1 integrase, respectively-nuclear enzymes which are over-expressed in deregulation disorders. Moreover, these compounds have been reported for their efficacy in treatment of multi-drug resistant (MDR) tumors cells without mediated drug efflux, as well as their immunomodulatory activity and selectivity towards melanoma cell lines. This article is an overview of recent literature on lamellarins, encompassing their isolation, recent synthetic strategies for their total synthesis, the preparation of their analogs, studies on their mechanisms of action, and their structure-activity relationships (SAR).     

Tumor cell targeting of liposome-entrapped drugs with phospholipid-anchored folic acid-PEG conjugates

Targeting of liposomes with phospholipid-anchored folate conjugates is an attractive approach to deliver chemotherapeutic agents to folate receptor (FR) expressing tumors. The use of polyethylene glycol (PEG)-coated liposomes with folate attached to the outer end of a small fraction of phospholipid-anchored PEG molecules appears to be the most appropriate way to combine long-circulating properties critical for liposome deposition in tumors and binding of liposomes to FR on tumor cells. Although a number of important formulation parameters remain to be optimized, there are indications, at least in one ascitic tumor model, that folate targeting shifts intra-tumor distribution of liposomes to the cellular compartment. In vitro, folate targeting enhances the cytotoxicity of liposomal drugs against FR-expressing tumor cells. In vivo, the therapeutic data are still fragmentary and appear to be formulation- and tumor model-dependent. Further studies are required to determine whether folate targeting can confer a clear advantage in efficacy and/or toxicity to liposomal drugs.     

叶酸代谢酶MTHFR、MTRR基因多态性与原因不明复发性流产的关系

目的 探讨叶酸代谢相关酶亚甲基四氢叶酸还原酶（MTHFR）、甲硫氨酸合酶还原酶（MTRR）基因多态性与原因不明复发性流产（URSA）之间的关系。 方法 采用病例对照的研究方法, 选取天津医科大学总医院和天津市妇女儿童保健中心 2013 年 1 月 1 日—2015 年 3 月 1 日因 URSA 就诊的非妊娠妇女 244 例（URSA 组）和健康非妊娠妇女 116 例（ 对照组）。 获取口腔黏膜上皮细胞, 使用荧光定量 PCR 检测 MTHFR 基因 C677T、A1298C 位点和 MTRR 基因 A66G 位点的单核苷酸多态性（SNP）, 同时测定 MTHFR 酶活性及红细胞叶酸、血浆叶酸、血浆同型半胱氨酸水平, 分析叶酸代谢相关酶 MTHFR、MTRR 基因多态性与 URSA 之间的关系。 结果 URSA 组 MTHFR C677T 位点 TT 基因型频率高于对照组, CT 基因型频率低于对照组（P＜ 0.05）。 2 组间 MTHFR A1298C、MTRR A66G 基因型频率差异无统计学意义。 URSA 组 MTHFR 酶活性、红细胞叶酸、血浆叶酸水平低于对照组, 同型半胱氨酸水平高于对照组（P＜ 0.05）; URSA 组中＜ 35 岁、≥35 岁患者血浆叶酸、红细胞叶酸、同型半胱氨酸水平差异无统计学意义。结论 MTHFR C677T 基因多态性与 URSA 有一定关系。     

Polymorphisms in genes involved in folate metabolism as maternal risk factors for Down syndrome — meta-analysis

Folate metabolism deficiency has been related to increased occurrence of maternal non-disjunction resulting in trisomy 21. Several polymorphisms in genes coding for folate metabolism enzymes have been investigated for association with the maternal risk of Down syndrome (DS) yielding variable results. We performed a meta-analysis of case-control studies obtained through the PubMed database. The studies on polymorphisms in the MTHFR, MTRR, MTR, RFC1 and CBS genes were included. The summary OR demonstrated a statistically significant increased risk of giving birth to a child with DS in mothers carrying the mutant allele of the MTHFR/C677T gene polymorphism (both genetic models) and in mothers homozygous for the mutant allele of the MTRR/A66G polymorphism (recessive genetic model). Analyses of other polymorphisms, MTHFR/A1298C, MTR/A2756G, RFC1/A80G, and CBS/844ins68, resulted in borderline or no statistical significance. In conclusion, our meta-analysis showed the significance of genetic alterations in the folate metabolism genes in maternal susceptibility to DS offspring. Our results suggest that the importance of folate supplementation to women in reproductive age in prevention of non-disjunction be revised. Further genetic studies on a combined effect of multiple folate metabolism genes is recommended. Additionally, more thorough studies on the haplotype analyses of genes is recommended as well, especially in populations that have not yet been investigated thus far.     

Hepatocyte cell lines: their use, scope and limitations in drug metabolism studies

Gaining knowledge on the metabolism of a drug, the enzymes involved and its inhibition or induction potential is a necessary step in pharmaceutical development of new compounds. Primary human hepatocytes are considered a cellular model of reference, as they express the majority of drug-metabolising enzymes, respond to enzyme inducers and are capable of generating in vitro a metabolic profile similar to what is found in vivo. However, hepatocytes show phenotypic instability and have a restricted accessibility. Different alternatives have been explored in the past recent years to overcome the limitations of primary hepatocytes. These include immortalisation of adult or fetal human hepatic cells by means of transforming tumour virus genes, oncogenes, conditionally immortalised hepatocytes, and cell fusion. New strategies are currently being used to upregulate the expression of drug-metabolising enzymes in cell lines or to derive hepatocytes from progenitor cells. This paper reviews the features of liver-derived cell lines, their suitability for drug metabolism studies as well as the state-of-the-art of the strategies pursued in order to generate metabolically competent hepatic cell lines.     

Antifolates in cancer therapy: Structure,activity and mechanisms of drug resistance

In the past 65 years, antifolates targeting folate metabolism played a pivotal role in drug treatment of malignant, microbial, parasitic and chronic inflammatory diseases. Drug discovery of novel antifolates with improved properties and superior activities remains an attractive strategy both in academia and in the pharmaceutical industry. Among novel antifolates are pemetrexed which primarily targets thymidylate synthase as well as pralatrexate which blocks dihydrofolate reductase, and displays enhanced transport and cellular retention properties. The present review describes the evolution and pharmacological activity of antifolates and prospects for the development of the next generation antifolates. Pre-clinical and clinical studies identified a plethora of mechanisms of antifolate resistance that are a primary hindrance to curative cancer chemotherapy; these are frequently associated with qualitative and/or quantitative alterations in influx and/or efflux transporters of antifolates and in folate-dependent enzymes. Current advances including for example the deciphering of the dominant folate transporter proton-coupled folate transporter (PCFT/SLC46A1) facilitated the synthesis of experimental antifolates aimed at selectively targeting solid tumor cells, which reside in an acidic microenvironment where PCFT supposedly functions optimally. Moreover, drugs that are structurally and mechanistically distinct from folates were conjugated to folic acid (e.g. Vintafolide/EC145, a folic acid desacetylvinblastine conjugate) to facilitate endocytosis via the folate receptor (FR) which is markedly overexpressed in various solid tumors. In an alternative approach, novel antifolates selectively targeting the FR but not other folate transporters are being developed (e.g. BGC 945). Hence, targeting mechanisms of antifolate-resistance could facilitate the development of rationally-based novel antifolates and strategies that overcome chemoresistance.     

Biological and clinical implications of the MTHFR C677T polymorphism

The enzyme methylenetetrahydrofolate reductase (MTHFR) directs folate species either to DNA synthesis or to homocysteine (Hcy) remethylation. The common MTHFR C677T polymorphism affects the activity of the enzyme and hence folate distribution. Under conditions of impaired folate status, the homozygous TT genotype has been regarded as harmful because it is associated with a high concentration of plasma total Hcy, increased risk of neural tube defects and colorectal neoplasias, and can also predispose individuals to adverse effects from drugs with antifolate effects. The MTHFR C677T polymorphism shows no consistent correlation with cardiovascular risk and longevity but, in combination with positive folate balance, the TT genotype is associated with decreased risk of colorectal neoplasias. Because of the high prevalence of this polymorphism in most populations, the TT variant might represent an ancestral genetic adaptation to living constraints (tissue injury or unbalanced vitamin intake) that has become a determinant of disease profiles in modern times.     

Targeted drug delivery via the folate receptor

The folate receptor is a highly selective tumor marker overexpressed in greater than 90% of ovarian carcinomas. Two general strategies have been developed for the targeted delivery of drugs to folate receptor-positive tumor cells: by coupling to a monoclonal antibody against the receptor and by coupling to a high affinity ligand, folic acid. First, antibodies against the folate receptor, including their fragments and derivatives, have been evaluated for tumor imaging and immunotherapy clinically and have shown significant targeting efficacy in ovarian cancer patients. Folic acid, a high affinity ligand of the folate receptor, retains its receptor binding properties when derivatized via its gamma-carboxyl. Folate conjugation, therefore, presents an alternative method of targeting the folate receptor. This second strategy has been successfully applied in vitro for the receptor-specific delivery of protein toxins, anti-T-cell receptor antibodies, interleukin-2, chemotherapy agents, gamma-emitting radiopharmaceuticals, magnetic resonance imaging contrast agents, liposomal drug carriers, and gene transfer vectors. Low molecular weight radiopharmaceuticals based on folate conjugates showed much more favorable pharmacokinetic properties than radiolabeled antibodies and greater tumor selectivity in folate receptor-positive animal tumor models. The small size, convenient availability, simple conjugation chemistry, and presumed lack of immunogenicity of folic acid make it an ideal ligand for targeted delivery to tumors.     

Modulation of carcinogen metabolism and DNA interaction by calcium glucarate in mouse skin.

Almost all the polycyclic aromatic hydrocarbons (PAHs) require metabolic activation to exert their carcinogenic activity. Environmental carcinogen [(3)H] benzo[a]pyrene (BP) is carcinogenic only after its metabolic transformation to a reactive intermediate, which can then bind to cellular macromolecules. Inhibition of dimethylbenz anthracene- (DMBA-) DNA binding generally accompanied inhibition of tumor initiation as most inhibitors of initiation interfere with the metabolic activation of the initiator. The importance of carcinogen-DNA interaction and the enzymes involved in the metabolism of carcinogenic polycyclic hydrocarbons has led to a search for inhibitors that would be useful in modifying the cancer-causing effects of the PAHs. We tested the effect of calcium glucarate (Cag), a naturally occurring nontoxic compound, on carcinogen metabolism and DNA interaction. Cag inhibited [(3)H] BP binding to both calf thymus DNA in vitro and to epidermal DNA in vivo. Application of Cag to mouse skin caused a dose-dependent inhibition of [(3)H] BP binding to epidermal DNA. To establish the relevance of the in vivo results to the in vitro situation, we followed the in vitro effect of Cag on [(3)H] BP binding to calf thymus DNA and observed that Cag inhibited the [(3)H] BP binding to calf thymus DNA in the presence of microsomes prepared from animals treated with DMBA. We also studied related events like DNA synthesis and carcinogen metabolism. For assessing the DNA synthesis, thymidine kinase was used as marker. Cag caused a dose-dependent inhibition of DMBA-induced thymidine kinase activity. At the same time, Cag caused a marked inhibition of DMBA-induced aryl hydrocarbon hydroxylase (AHH) activity, an enzyme responsible for the metabolism of PAHs like BP, both in vivo and in vitro. Our study indicates that Cag exerted its antitumor effect possibly by inhibiting the carcinogen-DNA binding, which appears to be due to reduced DNA synthesis and AHH activity.     

Liposomes as targeted drug delivery systems in the treatment of breast cancer

Solid tumors such as breast cancer have historically provided many challenges to anti-cancer therapy. Therapeutic hurdles to drug penetration in solid tumors include heterogeneous vascular supply and high interstitial pressures within tumor tissue, particularly in necrotic zones, lower pH and presence of leaky vasculature leading to reduced therapeutic response. Liposome based drug delivery systems offer the potential to enhance the therapeutic index of anti-cancer agents, either by increasing the drug concentration in tumor cells and/or by decreasing the exposure in normal tissues exploiting enhanced permeability and retention effect phenomenon and by utilizing targeting strategies. This review discusses recent trends in liposome-based drug delivery system both for diagnosis and treatment of breast cancer.