Development of CAPS and dCAPS markers for <Emphasis Type="Italic">CYP82E4</Emphasis>, <Emphasis Type="Italic">CYP82E5v2</Emphasis> and <Emphasis Type="Italic">CYP82E10</Emphasis> gene mutants reducing nicotine to nornicotine conversion in tobacco

Nornicotine accumulation in tobacco is of concern because nornicotine is a precursor of N-nitrosonornicotine (NNN), a tobacco constituent recognized as a carcinogen by the health community. Nornicotine is derived from nicotine through a demethylation process catalyzed by nicotine demethylase enzymes. Three genes (CYP82E4, CYP82E5v2, and CYP82E10) have currently been identified that encode for these enzymes. Ethyl methane sulfonate has been used to introduce mutations into each of these genes to prevent production of functional gene products. These mutants represent a valuable tool for reducing nornicotine and NNN levels in cured tobacco leaves and their derived products. Methods are currently needed to rapidly and efficiently develop new cultivars possessing these mutant alleles. The objective of this study was to develop efficient, user-friendly DNA markers to identify these mutations based on single nucleotide polymorphisms (SNPs). Four dCAPS (derived cleaved amplified polymorphic sequence) markers were designed for a truncation mutation in CYP82E4, and a single marker was developed for a similar mutation in CYP82E5v2. Two CAPS (cleaved amplified polymorphic sequence) markers were designed for a missense mutation in CYP82E10. Because of the co-dominant nature of the CAPS and dCAPS markers, heterozygous and homozygous plants can be easily differentiated. Genotypes determined by the CAPS and dCAPS marker methods were validated by DNA sequencing and phenotypic analysis of plants carrying various mutant combinations. These markers can be used in marker-assisted selection programs to quickly introgress the desired mutations into commercial varieties in order to reduce nornicotine and NNN levels in tobacco leaves.     

Transgenic and Mutation-Based Suppression of a Berberine Bridge Enzyme-Like (BBL) Gene Family Reduces Alkaloid Content in Field-Grown Tobacco

Motivation exists to develop tobacco cultivars with reduced nicotine content for the purpose of facilitating compliance with expected tobacco product regulations that could mandate the lowering of nicotine levels per se, or the reduction of carcinogenic alkaloid-derived tobacco specific nitrosamines (TSNAs). A berberine bridge enzyme-like (BBL) gene family was recently characterized for N. tabacum and found to catalyze one of the final steps in pyridine alkaloid synthesis for this species. Because this gene family acts downstream in the nicotine biosynthetic pathway, it may represent an attractive target for genetic strategies with the objective of reducing alkaloid content in field-grown tobacco. In this research, we produced transgenic doubled haploid lines of tobacco cultivar K326 carrying an RNAi construct designed to reduce expression of the BBL gene family. Field-grown transgenic lines carrying functional RNAi constructs exhibited average cured leaf nicotine levels of 0.684%, in comparison to 2.454% for the untransformed control. Since numerous barriers would need to be overcome to commercialize transgenic tobacco cultivars, we subsequently pursued a mutation breeding approach to identify EMS-induced mutations in the three most highly expressed isoforms of the BBL gene family. Field evaluation of individuals possessing different homozygous combinations of truncation mutations in BBLa, BBLb, and BBLc indicated that a range of alkaloid phenotypes could be produced, with the triple homozygous knockout genotype exhibiting greater than a 13-fold reduction in percent total alkaloids. The novel source of genetic variability described here may be useful in future tobacco breeding for varied alkaloid levels.     

Expression of a constitutively active nitrate reductase variant in tobacco reduces tobacco‐specific nitrosamine accumulation in cured leaves and cigarette smoke

Burley tobaccos (Nicotiana tabacum) display a nitrogen‐use‐deficiency phenotype that is associated with the accumulation of high levels of nitrate within the leaf, a trait correlated with production of a class of compounds referred to as tobacco‐specific nitrosamines (TSNAs). Two TSNA species, 4‐(methylnitrosamino)‐1‐(3‐pyridyl)‐1‐butanone (NNK) and N‐nitrosonornicotine (NNN), have been shown to be strong carcinogens in numerous animal studies. We investigated the potential of molecular genetic strategies to lower nitrate levels in burley tobaccos by overexpressing genes encoding key enzymes of the nitrogen‐assimilation pathway. Of the various constructs tested, only the expression of a constitutively active nitrate reductase (NR) dramatically decreased free nitrate levels in the leaves. Field‐grown tobacco plants expressing this NR variant exhibited greatly reduced levels of TSNAs in both cured leaves and mainstream smoke of cigarettes made from these materials. Decreasing leaf nitrate levels via expression of a constitutively active NR enzyme represents an exceptionally promising means for reducing the production of NNN and NNK, two of the most well‐documented animal carcinogens found in tobacco products.     

Radioimmunoassay of N'-nitrosonornicotine.

Antibodies specific for the precarcinogen N′-nitrosonornicotine (NNN) were obtained in rabbits immunized with a N′-nitroso-5′-carboxynornicotine-human serum albumin conjugate. The NNN derivative was synthesized by reduction and nitrosation of 2′,3′-dehydronornicotine and covalently conjugated to the macromolecule with the use of a carbodiimide. A radioimmunoassay was developed which could detect as little as 0.2 ng of NNN. Analyses of plasma supplemented with NNN indicated that it was possible to detect 2 ng NNN/ml sample. Nicotine, cotinine, pyridine, and pyrrolidine derivatives are ineffective inhibitors of the antigen-antibody reaction. N′-Nitrosoanabasine inhibits effectively, but this derivative has been reported not to occur in tobacco. The radioimmunoassay has been used to monitor nitrosation of nornicotine and anabasine under chemical conditions and to determine the rate constants for the reactions.     

烟草去甲基尼古丁产生的机理

烟叶的采收后处理和加工过程中,大量的尼古丁经去甲基化作用生成了去甲基尼古丁,后者是烟草特有的亚硝胺类（tobacco-specific nitrosamines,TSNAs）致癌物——亚硝基去甲基尼古丁（nitrosonomicoline,NNN）的前体,与人类健康息息相关。由于尼古丁去甲基化反应在基础理论研究和商业上的重要价值,长期以来关于这个反应的机制研究一直是学术界的热点。本文讨论了尼古丁去甲基化反应研究的历史概况、反应机制假说的演变及影响该反应的因素,期望通过对烟草尼古丁去甲基化反应研究的总结,为烟草品质提高和低毒害烟草制品的研究与开发提供一定的参考。     

Three nicotine demethylase genes mediate nornicotine biosynthesis in Nicotiana tabacum L.: functional characterization of the CYP82E10 gene

In most tobacco (Nicotiana tabacum L.) plants, nornicotine is a relatively minor alkaloid, comprising about 2-5% of the total pyridine alkaloid pool in the mature leaf. Changes in gene expression at an unstable locus, however, can give rise to plants that produce high levels of nornicotine, specifically during leaf senescence and curing. Minimizing the nornicotine content in tobacco is highly desirable, because this compound serves as the direct precursor in the synthesis of N'-nitrosonornicotine, a potent carcinogen in laboratory animals. Nornicotine is likely produced almost entirely via the N-demethylation of nicotine, in a process called nicotine conversion that is catalyzed by the enzyme nicotine N-demethylase (NND). Previous studies have identified CYP82E4 as the specific NND gene responsible for the unstable conversion phenomenon, and CYP82E5v2 as a putative minor NND gene. Here, by discovery and characterization of CYP82E10, a tobacco NND gene, is reported. PCR amplification studies showed that CYP82E10 originated from the N. sylvestris ancestral parent of modern tobacco. Using a chemical mutagenesis strategy, knockout mutations were induced and identified in all three tobacco NND genes. By generating a series of mutant NND genotypes, the relative contribution of each NND gene toward the nornicotine content of the plant was assessed. Plants possessing knockout mutations in all three genes displayed nornicotine phenotypes that were much lower (～0.5% of total alkaloid content) than that found in conventional tobacco cultivars. The introduction of these mutations into commercial breeding lines promises to be a viable strategy for reducing the levels of one of the best characterized animal carcinogens found in tobacco products.     

烟草去甲基尼古丁产生的机理

烟叶的采收后处理和加工过程中, 大量的尼古丁经去甲基化作用生成了去甲基尼古丁, 后者是烟草特有的亚硝胺类(tobacco-specific nitrosamines, TSNAs)致癌物— — 亚硝基去甲基尼古丁(nitrosonornicotine, NNN)的前体, 与人类健康息息相关。由于尼古丁去甲基化反应在基础理论研究和商业上的重要价值, 长期以来关于这个反应的机制研究一直是学术界的热点。本文讨论了尼古丁去甲基化反应研究的历史概况、反应机制假说的演变及影响该反应的因素, 期望通过对烟草尼古丁去甲基化反应研究的总结, 为烟草品质提高和低毒害烟草制品的研究与开发提供一定的参考。     

Application of exogenous substances reduces tobacco-specific nitrosamines content by regulating biosynthesis of nicotine and nitrite in burley tobacco

Tobacco-specific nitrosamines (TSNAs) are carcinogenic chemicals found in tobacco plants. The increasing health consciousness of individuals had led to an increased interest in research on reducing TSNAs content. The aim of this study was to use a pot experiment in which exogenous substances were applied to burley tobacco to dissect the mechanism of TSNAs production. The results indicated that spraying the exogenous substances IAA, NAA, SA and combination thereof on burley tobacco after topping decreased TSNAs content by 2.69–29.4 % in upper leaves and 0.23–39.3 % in middle leaves without affecting total sugar, total nitrogen, potassium and chlorine contents. The application of exogenous substances could down-regulate expression of the NR gene and the activity of the NR enzyme, resulting in less accumulation of the TSNAs precursor nitrite. The exogenous substances significantly reduced nicotine accumulation, which was consistent with low enzyme activities and the down-regulated expressions of genes involved in nicotine biosynthesis, especially significant in the case of quinolinate phosphoribosyltransferase. These results suggested that the application of exogenous substances on burley tobacco after topping could reduce TSNAs content which may be attributed to the regulation of exogenous substances on nitrite and nicotine. This also implies one potential improvement to agronomic practices aimed at controlling the accumulation of TSNAs in burley tobacco.     

Enantioselective Demethylation of Nicotine as a Mechanism for Variable Nornicotine Composition in Tobacco Leaf

Nicotine and its N-demethylation product nornicotine are two important alkaloids in Nicotiana tabacum L. (tobacco). Both nicotine and nornicotine have two stereoisomers that differ from each other at 2′-C position on the pyrrolidine ring. (S)-Nicotine is the predominant form in the tobacco leaf, whereas the (R)-enantiomer only accounts for ∼0.2% of the total nicotine pool. Despite considerable past efforts, a comprehensive understanding of the factors responsible for generating an elevated and variable enantiomer fraction of nornicotine (EF_nnic of 0.04 to 0.75) from the consistently low EF observed for nicotine has been lacking. The objective of this study was to determine potential roles of enantioselective demethylation in the formation of the nornicotine EF. Recombinant CYP82E4, CYP82E5v2, and CYP82E10, three known tobacco nicotine demethylases, were expressed in yeast and assayed for their enantioselectivities in vitro. Recombinant CYP82E4, CYP82E5v2, and CYP82E10 demethylated (R)-nicotine 3-, 10-, and 10-fold faster than (S)-nicotine, respectively. The combined enantioselective properties of the three nicotine demethylases can reasonably account for the nornicotine composition observed in tobacco leaves, which was confirmed in planta. Collectively, our studies suggest that an enantioselective mechanism facilitates the maintenance of a reduced (R)-nicotine pool and, depending on the relative abundances of the three nicotine demethylase enzymes, can confer a high (R)-enantiomer percentage within the nornicotine fraction of the leaf.     

Determination of tobacco-specific N-nitrosamines in urine of smokers and non-smokers

Tobacco-specific N-nitrosamines (TSNA) include 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK), N′-nitrosonornicotine (NNN), N′-nitrosoanabasine (NAB) and N′-nitrosoanatabine (NAT) and are found in tobacco and tobacco smoke. TSNA are of interest for biomonitoring of tobacco-smoke exposure as they are associated with carcinogenesis. Both NNK and NNN are classified by IARC as Group 1 carcinogens. Samples of 24?h urine collections (n?=?108) were analysed from smokers and non-smokers, using a newly developed and validated LC-MS/MS method for determining total 4-(methylnitrosamino)-1-(3-pyridyl)-1-butanol (NNAL, the major metabolite of NNK), and total NNN, NAB and NAT. TSNA levels in smokers’ urine were significantly higher than in non-smokers. In smokers, urinary excretion of total TSNA correlated significantly (r?>?0.5) with markers of smoking dose, such as daily cigarette consumption, salivary cotinine and urinary nicotine equivalents and increased with the ISO tar yield of cigarettes smoked. The correlation between urinary total NNN and the smoking dose was weaker (r?=?0.4–0.5). In conclusion, this new method is suitable for assessing tobacco use-related exposure to NNK, NNN, NAB and NAT.     

The Only African Wild Tobacco,Nicotiana africana: Alkaloid Content and the Effect of Herbivory

Herbivory in some Nicotiana species is known to induce alkaloid production. This study examined herbivore-induced defenses in the nornicotine-rich African tobacco N. africana, the only Nicotiana species indigenous to Africa. We tested the predictions that: 1) N. africana will have high constitutive levels of leaf, flower and nectar alkaloids; 2) leaf herbivory by the African bollworm Helicoverpa armigera will induce increased alkaloid levels in leaves, flowers and nectar; and 3) increased alkaloid concentrations in herbivore-damaged plants will negatively affect larval growth. We grew N. africana in large pots in a greenhouse and exposed flowering plants to densities of one, three and six fourth-instar larvae of H. armigera, for four days. Leaves, flowers and nectar were analyzed for nicotine, nornicotine and anabasine. The principal leaf alkaloid was nornicotine (mean: 28 µg/g dry mass) followed by anabasine (4.9 µg/g) and nicotine (0.6 µg/g). Nornicotine was found in low quantities in the flowers, but no nicotine or anabasine were recorded. The nectar contained none of the alkaloids measured. Larval growth was reduced when leaves of flowering plants were exposed to six larvae. As predicted by the optimal defense theory, herbivory had a localized effect and caused an increase in nornicotine concentrations in both undamaged top leaves of herbivore damaged plants and herbivore damaged leaves exposed to one and three larvae. The nicotine concentration increased in damaged compared to undamaged middle leaves. The nornicotine concentration was lower in damaged leaves of plants exposed to six compared to three larvae, suggesting that N. africana rather invests in new growth as opposed to protecting older leaves under severe attack. The results indicate that the nornicotine-rich N. africana will be unattractive to herbivores and more so when damaged, but that potential pollinators will be unaffected because the nectar remains alkaloid-free even after herbivory.     

Modified alkaloid pattern in developing tobacco callus

Developing Nicotiana tabacum L. cv. Wisconsin-38 callus grown on modified Murashige-Skoog (MS) medium with Kao organic acids (pyruvic, citric, malic and fumaric acids) contains abnormally high levels of nornicotine and total alkaloids when compared with the leaves of the donor plant. Nornicotine/nicotine ratios observed during callus development suggest that nicotine is converted into nornicotine in the callus, with subsequent movement of alkaloids into roots formed on the callus and into the agar medium. Addition of Kao organic acids to the medium increases alkaloid levels, but cannot account for the abnormal increase in nicotine demethylation. This study thus reports two new findings: (a) that the total alkaloid content of tobacco callus can be greatly enhanced to 3.75% on a dry weight basis by exogenous organic acids, and (b) that endogenous nornicotine can accumulate in tobacco tissue cultures.     

Generation of tobacco lines with widely different reduction in nicotine levels via RNA silencing approaches

Issues related to the nicotine content of tobacco have been public concerns.Several reports have described decreasing nicotine levels by silencing the putrescine N-methyltransferase (PMT) genes, but the reported variations of nicotine levels among transgenic lines are relatively low in general. Here we describe the generation in tobacco (Nicotiana tabacum) lines with widely different, reduced nicotine levels using three kinds of RNA-silencing approaches.The relative efficacies of suppression were compared among the three approaches regarding the aspect of nicotine level in tobacco leaves.By suppressing expression of the PMT genes, over 200 transgenic lines were obtained with nicotine levels reduced by 9.1-96.7%. RNA interference (RNAi) was the most efficient method of reducing the levels of nicotine,whereas cosuppression and antisense methods were less effective. This report gives clues to the efficient generation of plants with a variety of metabolite levels, and the results demonstrate the relative efficiencies of various RNA-silencing methods.     

烟草尼古丁去甲基化酶基因及其在育种中的应用

尼古丁通过去甲基化反应生成去甲基尼古丁,后者是潜在的致癌物质亚硝基去甲基尼古丁的合成前体,可能对人体健康产生危害.尼古丁去甲基化酶基因最近被克隆并进化分析,这些基因还作为目标基因应用于低去甲基尼古丁烟草品种选育.该文对近年来该领域研究进展进行综述,并展望该领域未来的研究方向.     

Biochemical and molecular characterizations of nicotine demethylase in tobacco

Plant cytochrome P450 (CYP) enzymes are involved in the biosynthesis of many primary and secondary metabolites including phenylpropanoids, alkaloids, terpenoids, lipids, cyanogenic glycosides, and glucosinolates. However, while hundreds of CYP genes have been identified in plant genomes, relatively few have been functionally characterized. We report here the cloning and characterization of a CYP enzyme from tobacco (Nicotiana tabacum L.) that demethylates nicotine to form nornicotine, a precursor to the nitrosamine N′‐nitrosonornicotine (NNN). Microsomal demethylase activity was first shown to be induced in leaves treated with the growth regulator ethylene, required molecular oxygen and reduced form of nicotinamide adenine dinucleotide phosphate (NADPH) for full activity, and exhibited a K_m of 3.9 μM for nicotine and a maximum turnover rate (V_max) of 8.9 pkat mg⁻¹ protein. Equally important, microsomal activity was reduced greatly by several inhibitors of CYP‐mediated reactions. Using a polymerase chain reaction based strategy with degenerate primers designed to conserve P450 motifs and mRNA from ethylene‐treated leaves, putative gene fragments representing 32 different P450 gene families were isolated and numerous full‐length genes were cloned. Employing GeneChip^® (Affymetrix Inc., Santa Clara, CA) microarray hybridizations, the steady‐state mRNA level of two highly related full‐length cDNAs and one cDNA fragment were demonstrated to be highly expressed in ethylene‐treated vs. control plant material. Microsomes from yeast over‐expressing the two full‐length cDNAs along with two other highly homologous P450 genes demonstrated that only one cDNA, D121‐AA8 (GenBank accession no. DQ205656) encoded for demethylation activity comparable to that found in planta. Molecular modeling was used to identify putative active site residues and for comparisons to other putative demethylase cDNAs.