Interaction of PvALF and VP1 B3 domains with the β-phaseolin promoter

Caffeine (1,3,7-trimethylxanthine) is derived from xanthosine through three successive transfers of methyl groups and a single ribose removal in coffee plants. The methyl group transfer is catalyzed by N-zmethyltransferases, xanthosine methyltransferase (XMT), 7-methylxanthine methyltransferase (MXMT) and 3,7-dimethylxanthine methyltransferase (DXMT). We previously cloned three genes encoding each of these N-methyltransferases from coffee plants, and reconstituted the final sequence of the caffeine synthetic pathway in vitro. In the present study, we simultaneously expressed these coffee genes in tobacco plants (Nicotiana tabacum), using a multiple-gene transfer method, and confirmed successful caffeine production up to 5 μg g⁻¹ fresh weight in leaves of the resulting transgenic plants. Their effects on feeding behavior of tobacco cutworms (Spodoptera litura), which damage a wide range of crops, were then examined. Leaf disc choice test showed that caterpillars selectively fed on the wild-type control materials, or positively avoided the transgenic materials. The results suggest a novel approach to confer self-defense by producing caffeine in planta. A second generation of transgenic crops containing caffeine may save labor and agricultural costs and also mitigate the environmental load of pesticides in future.     

Metabolic Engineering of Saccharomyces cerevisiae for Caffeine and Theobromine Production

Caffeine (1, 3, 7-trimethylxanthine) and theobromine (3, 7-dimethylxanthine) are the major purine alkaloids in plants, e.g. tea (Camellia sinensis) and coffee (Coffea arabica). Caffeine is a major component of coffee and is used widely in food and beverage industries. Most of the enzymes involved in the caffeine biosynthetic pathway have been reported previously. Here, we demonstrated the biosynthesis of caffeine (0.38 mg/L) by co-expression of Coffea arabica xanthosine methyltransferase (CaXMT) and Camellia sinensis caffeine synthase (TCS) in Saccharomyces cerevisiae. Furthermore, we endeavored to develop this production platform for making other purine-based alkaloids. To increase the catalytic activity of TCS in an effort to increase theobromine production, we identified four amino acid residues based on structural analyses of 3D-model of TCS. Two TCS1 mutants (Val317Met and Phe217Trp) slightly increased in theobromine accumulation and simultaneously decreased in caffeine production. The application and further optimization of this biosynthetic platform are discussed.     

Caffeine biosynthesis and adenine metabolism in transgenic Coffea canephora plants with reduced expression of N-methyltransferase genes

In anti-sense and RNA interference transgenic plants of Coffea canephora in which the expression of CaMXMT1 was suppressed, caffeine biosynthesis from [8-(14)C]adenine was investigated, together with the overall metabolism of [8-(14)C]adenine. Compared with wild type control plants, total purine alkaloid biosynthesis from adenine and conversion of theobromine to caffeine were both reduced in the transgenic plants. As found previously, [8-(14)C]adenine was metabolised to salvage products (nucleotides and RNA), to degradation products (ureides and CO(2)) and to purine alkaloids (theobromine and caffeine). In the transgenic plants, metabolism of [8-(14)C]adenine shifted from purine alkaloid synthesis to purine catabolism or salvage for nucleotides. HPLC analysis revealed a significantly reduced caffeine content in the transgenic plants. A small quantity (less than 20 nmol g(-1) fresh weight) of xanthosine had accumulated in at least one of the transgenic plants.     

CaXMT和TCS1突变体基因串联共表达及体外酶活检测分析

咖啡碱和可可碱是茶叶生物碱的主要组分,且咖啡碱是茶叶重要的滋味物质,随着咖啡碱在食品和药物领域的应用愈发广泛,咖啡碱的生物合成成为新的研究热点.目前市场上的咖啡碱主要靠化学合成,为了探索其生物合成途径,该研究将咖啡黄嘌呤核苷甲基转移酶(coffee xanthosine methyltransferase,CaXMT)基因和茶树咖啡碱合成酶(tea caffeine synthase,TCS1)基因的4个突变体分别串联至同一大肠杆菌表达载体pMAL-c5X,诱导融合蛋白共表达,并进行SDS-PAGE凝胶电泳分析.结果表明:目的蛋白成功表达后,应用超声破碎法制备含有目的蛋白的粗酶液,添加底物黄嘌呤核苷(xanthosine,XR)和甲基供体S-腺苷甲硫氨酸(S-adenosyl-L-methionine,SAM)进行体外酶促反应,将反应产物进行高效液相色谱检测.检测结果显示,pMAL-CaXMT-TM2/3/4的体外酶促反应产物仅有可可碱生成,均未见咖啡碱生成.该研究结果为构建生物合成咖啡碱和可可碱的串联共表达载体奠定了基础,也为进一步研究生物合成咖啡碱和可可碱提供了新思路.     

Biosynthesis of Caffeine in Leaves of Coffee

The levels of endogenous caffeine and theobromine were much higher in buds and young leaves of Coffea arabica L. cv Kent than in fully developed leaves. Biosynthesis of caffeine from 14C-labeled adenine, guanine, xanthosine, and theobromine was observed, whereas other studies (H. Ashihara, A.M. Monteiro, T. Moritz, F.M. Gillies, A. Crozier [1996] Planta 198: 334-339) have indicated that there is no detectable incorporation of label into caffeine when theophylline and xanthine are used as substrates for in vivo feeds with leaves of C. arabica. The capacity for caffeine biosynthesis, especially from guanine and xanthosine, was reduced markedly in both fully developed mature and aged leaves. Data obtained in pulse-chase experiments with young leaves indicate the operation of an AMP -> IMP -> xanthosine 5[prime]-monophosphate (or GMP -> guanosine) -> xanthosine -> 7-methylxanthosine -> 7-methylxanthine -> theobromine -> caffeine pathway. The data obtained provide strong evidence against proposals by G.M. Nazario and C.J. Lovatt ([1993] Plant Physiol 103: 1203-1210) concerning the independence of caffeine and theobromine biosynthesis pathways and the role of xanthine as a key intermediate in caffeine biosynthesis.     

N-methyltransferases and 7-methyl-N9-nucleoside hydrolase activity in Coffea arabica and the biosynthesis of caffeine

The incorporation of radioactivity from L-[¹⁴CH₃]-methionine into caffeine by coffee fruits was enhanced by additions of theobromine and paraxanthine but was reduced by additions of theophylline and caffeine. Cell-free extracts prepared from seedlings, partially ripe and unripe coffee fruits showed that only the unripe green fruits contained significant methyltransferase and 7-methyl-N⁹-nucleoside hydrolase activity. The cell-free extracts catalysed the transfer of methyl groups fromS-adenosyl-L-[¹⁴CH₃]-methionine to 7-methylxanthine, and 7-methylxanthosine, producing theobromine and to theobromine producing caffeine. The two enzymic methylations exhibited a sharp pH max at 8.5 and a similar pattern of effects with metal chelators, thiol reagents and Mg²⁺ ions, which were slightly stimulating though not essential to enzyme activity. Paraxanthine (1,7-dimethylxanthine) was sh own to be the most active among methylxanthines as methyl acceptors; however its formation from 1-methylxanthine and 7-methylxanthine was not detectable, and biosynthesis from paraxanthine in the intact plant would therefore appear not to occur. The apparent K_m values are as follows: 7-methylxanthine 0.2 mM, theobromine 0.2 mM, paraxanthine 0.07 mM and S-adenosyl-L-methionine with each substrate 0.01 mM. The results suggest the pathway for caffeine biosynthesis in Coffea arabica is: 7-methylxanthosine → 7-methylxanthine → theobromine → caffeine.     

Somatic embryogenesis: A valuable alternative for propagating selected robusta coffee (Coffea canephora) clones

In Vitro Cellular &; Developmental Biology - Plant - The behavior of four coffee (Coffea canephora cv. Robusta) clones was evaluated in this work to define the conditions that would allõw...     

N-methyltransferase activities in suspension cultures of Coffea arabica L.

Suspension cultures of Coffea arabica L. are a useful source for methyltransferase preparations of high activity catalysing the transfer of methylgroups from S-adenosyl-L-methionine to 7-methylxanthine and to theobromine producing theobromine and caffeine respectively. Surprisingly, these enzyme activities are not correlated with the availability of precursors during a culture cycle. They are highest in the growth phase when supply of precursors is reduced. Mixed substrate experiments and time dependent changes in the enzyme activity ratio provide indirect evidence for the existence of two separate enzymes catalysing the final methylations in caffeine biosynthesis.     

Genetic mapping of a caffeoyl-coenzyme A 3-O-methyltransferase gene in coffee trees. Impact on chlorogenic acid content

Chlorogenic acids (CGA) are involved in the bitterness of coffee due to their decomposition in phenolic compounds during roasting. CGA mainly include caffeoyl-quinic acids (CQA), dicaffeoyl-quinic acids (diCQA) and feruloyl-quinic acids (FQA), while CQA and diCQA constitute CGA sensu stricto (CGA s.s.). In the two cultivated species Coffea canephora and Coffea arabica, CGA s.s. represents 88% and 95% of total CGA, respectively. Among all enzymes involved in CGA biosynthesis, caffeoyl-coenzyme A 3-O-methyltransferase (CCoAOMT) is not directly involved in the CGA s.s. pathway, but rather in an upstream branch leading to FQA through feruloyl-CoA. We describe how a partial cDNA corresponding to a CCoAOMT encoding gene was obtained and sequenced. Specific primers were designed and used for studying polymorphism and locating the corresponding gene on a genetic map obtained from an interspecific backcross between Coffea liberica var. Dewevrei and Coffea pseudozanguebariae. Offspring of this backcross were also evaluated for the chlorogenic acid content in their green beans. A 10% decrease was observed in backcross progenies that possess one C. pseudozanguebariae allele of the CCoAOMT gene. This suggests that CGA s.s. accumulation is dependent on the CCoAMT allele present and consequently on the activity of the encoded isoform, whereby CGA accumulation increases as the isoform activity decreases. Possible implications in coffee breeding are discussed.     

Caffeine biosynthesis in young leaves of Camellia sinensis: In vitro studies on N-methyltransferase activity involved in the conversion of xanthosine to caffeine

The aim of this study was to investigate the S -adenosylmethionine dependent N -methyltransferase(s) (NMT) associated with the three methylation steps in the caffeine biosynthesis pathway in tea ( Camellia sinensis L.). NMT activity in cell-free preparations from young leaves was purified by anion-exchange and gel-filtration column chromatography. In both systems, a single zone of NMT activity, with broad substrate specificity was detected. The N-3 position of dimethylxanthine and monomethylxanthines was methylated more readily than N-1 while comparatively little substitution occurred at the N-7 locus. When xanthosine was used as a substrate only the N-7 position was methylated. These results indicate that a single NMT may participate in the conversion of xanthosine to caffeine. The apparent M_r of the NMT, estimated by gel filtration chromatography, was 61 000. The substrate specificity of the NMT is compatible with the operation of a xanthosine → 7-methylxanthosine → 7-methylxanthine → theobromine → caffeine pathway as the main biosynthetic route to caffeine in young tea leaves. The data also indicate that the conversion of 7-methylxanthine → paraxanthine → caffeine may function as one of a number of minor pathways that also contribute to the production of caffeine.     

Caffeine biosynthesis in young leaves of Camellia sinensis: In vitro studies on N-methyltransferase activity involved in the conversion of xanthosine to caffeine

The aim of this study was to investigate the S -adenosylmethionine dependent N -methyltransferase(s) (NMT) associated with the three methylation steps in the caffeine biosynthesis pathway in tea ( Camellia sinensis L.). NMT activity in cell-free preparations from young leaves was purified by anion-exchange and gel-filtration column chromatography. In both systems, a single zone of NMT activity, with broad substrate specificity was detected. The N-3 position of dimethylxanthine and monomethylxanthines was methylated more readily than N-1 while comparatively little substitution occurred at the N-7 locus. When xanthosine was used as a substrate only the N-7 position was methylated. These results indicate that a single NMT may participate in the conversion of xanthosine to caffeine. The apparent M_r of the NMT, estimated by gel filtration chromatography, was 61 000. The substrate specificity of the NMT is compatible with the operation of a xanthosine → 7-methylxanthosine → 7-methylxanthine → theobromine → caffeine pathway as the main biosynthetic route to caffeine in young tea leaves. The data also indicate that the conversion of 7-methylxanthine → paraxanthine → caffeine may function as one of a number of minor pathways that also contribute to the production of caffeine.     

Differential regulation of grain sucrose accumulation and metabolism in Coffea arabica (Arabica) and Coffea canephora (Robusta) revealed through gene expression and enzyme activity analysis

* Coffea arabica (Arabica) and Coffea canephora (Robusta) are the two main cultivated species used for coffee bean production. Arabica genotypes generally produce a higher coffee quality than Robusta genotypes. Understanding the genetic basis for sucrose accumulation during coffee grain maturation is an important goal because sucrose is an important coffee flavor precursor. * Nine new Coffea genes encoding sucrose metabolism enzymes have been identified: sucrose phosphate synthase (CcSPS1, CcSPS2), sucrose phosphate phosphatase (CcSP1), cytoplasmic (CaInv3) and cell wall (CcInv4) invertases and four invertase inhibitors (CcInvI1, 2, 3, 4). * Activities and mRNA abundance of the sucrose metabolism enzymes were compared at different developmental stages in Arabica and Robusta grains, characterized by different sucrose contents in mature grain. * It is concluded that Robusta accumulates less sucrose than Arabica for two reasons: Robusta has higher sucrose synthase and acid invertase activities early in grain development - the expression of CcSS1 and CcInv2 appears to be crucial at this stage and Robusta has a lower SPS activity and low CcSPS1 expression at the final stages of grain development and hence has less capacity for sucrose re-synthesis. Regulation of vacuolar invertase CcInv2 activity by invertase inhibitors CcInvI2 and/or CcInvI3 during Arabica grain development is considered.     

Bee pollination and fruit set of Coffea arabica and C. canephora (Rubiaceae)

Self-sterile Coffea canephora and self-fertile C. arabica are important cash crops in many tropical countries. We examined the relative importance of insect, wind, and spontaneous self-pollination and the degree of self-fertility of these two coffee species in 24 agroforestry coffee fields in Indonesia. In both species, open pollination and cross pollination by hand led to the highest fruit set. Wind pollination (including self-pollination) led to 16% lower fruit set than open pollination in C. canephora and to 12.3% lower fruit set in C. arabica. Self-pollinated flowers and unmanipulated controls achieved an extremely low fruit set of 10% or less in the self-sterile species, and of 60% and 48%, respectively in the self-fertile species. These results constitute experimental evidence that cross pollination by bees causes a significant increase in fruit set of not only the self-sterile, but also the self-fertile coffee species. The practical implication is that coffee yield may be improved by managing fields for increased flower visitation by bees.     

Evolution in caffeoylquinic acid content and histolocalization during Coffea canephora leaf development

BACKGROUND AND AIMS: Caffeoylquinic acids are cinnamate conjugates derived from the phenylpropanoid pathway. They are generally involved in plant responses to biotic and abiotic stress and one of them, chlorogenic acid (5-O-caffeoylquinic acid, 5-CQA), is an intermediate in the lignin biosynthesis pathway. Caffeoylquinic acids, and particularly 5-CQA, are accumulated in coffee beans, where they can form vacuolar complexes with caffeine. Coffea canephora beans are known to have high caffeoylquinic acid content, but little is known about the content and diversity of these compounds in other plant parts. To gain new insights into the caffeoylquinic acid metabolism of C. canephora, caffeoylquinic acid content and in situ localization were assessed in leaves at different growth stages. METHODS: HPLC analyses of caffeoylquinic acid content of leaves was conducted in conjunction with detailed histochemical and microspectrofluorometrical analysis. KEY RESULTS AND CONCLUSIONS: HPLC analyses revealed that caffeoylquinic acid content was 10-fold lower in adult than in juvenile leaves. The most abundant cinnamate conjugate was 5-CQA, but dicaffeoylquinic acids (particularly in juvenile leaves) and feruloylquinic acids were also present. Using specific reagents, histochemical and microspectrofluorometrical analysis showed that caffeoylquinic acids (mono- and di-esters) were closely associated with chloroplasts in very young leaves. During leaf ageing, they were found to first accumulate intensively in specific chlorenchymatous bundle sheath cells and then in phloem sclerenchyma cells. The association with chloroplasts suggests that caffeoylquinic acids have a protective role against light damage. In older tissues, their presence in the leaf vascular system indicates that they are transported via phloem and confirms their involvement in lignification processes. In accordance with the hypothesis of a complex formation with caffeine, similar tissue distribution was observed for alkaloids and this is further discussed.