作物叶酸生物强化

叶酸(folates)是一类水溶性B族维生素,包括四氢叶酸(tetrahydrofolate,THF)及其衍生物,是动植物体中参与C1转移反应的重要辅酶,在嘌呤、胸苷酸、DNA、氨基酸和蛋白质的生物合成以及甲基循环中发挥重要作用,也是动植物体生长发育所必需的微量营养素。由于人类不具备自身合成叶酸的能力,因此,需要从植物和微生物中摄取。人类缺乏叶酸会增加许多疾病风险,全球叶酸缺乏的人群仍比较普遍,利用生物强化提高作物的叶酸含量是一个解决全球性叶酸缺乏问题的有效方法,对人类生存与健康具有重要意义。现综述了近年来国内外叶酸代谢和作物叶酸生物强化的主要研究成果,并对叶酸生物强化分子设计育种的未来发展方向进行了展望。     

泛酸的功能和生物合成

泛酸是辅酶A(CoA)和酰基载体蛋白(ACP)生物合成的重要前体物质,参与生物体内碳水化合物、脂肪酸、蛋白质和能量代谢.在人体中还参与类固醇,褪黑激素、抗体和亚铁血红素的合成.生物体内的泛酸合成是由酮泛解酸羟甲基转移酶(PanB),酮泛解酸还原酶(PanE),L-天冬氨酸-α-脱羧酶(PanD)和泛酸合成酶(PanC)四种酶协同催化下完成的.由于泛酸合成途径只存在于植物和低等生物中,选择该生物合成途径酶作为药物靶点将会有高度的选择性.本文综述了泛酸的功能和已经研究清楚大肠杆菌和分支结核杆菌中的泛酸生物合成途径所涉及的酶的结构和特性.     

甲醇对植物的作用及其生理机制

甲醇是植物生长发育和代谢过程中体内产生的最简单的一碳化合物之一,与植物的很多生理过程(如光合作用、C1-四氢叶酸和某些植物激素生物合成以及植物耐逆性等)密切相关。本文对近年来国内外有关植物中甲醇的产生与释放途径、体内代谢、外施甲醇对植物的效应及其生理机制等方面研究进行了综述,并提出存在的问题和今后研究方向。     

植物花青素苷生物合成及调控的研究进展

花青素苷( anthocyanin)是植物新陈代谢过程中产生的类黄酮物质,决定被子植物花、果实、种皮、茎、叶和根等的颜色,具有重要的营养价值和药理作用.近年来关于花青素生物合成途径的研究已取得突破,综述了植物花青素苷基因研究现状和发展趋势,包括植物花青素生物合成途径、参与生物合成途径中相关的结构基因和调控基因及功能研究以及影响花青素苷生物合成的环境因素等的研究进展.     

芳香族氨基酸脱羧酶研究进展

芳香族氨基酸脱羧酶(aromatic L-amino acid decarboxylases, AADCs)在生物体内的作用是将芳香族氨基酸脱羧转化为芳香族单胺(aromatic monoamines),磷酸吡哆醛(pyridoxal 5′-phosphate, PLP)是其行使催化功能时必不可少的辅酶。AADCs催化芳香族氨基酸产生的芳香族单胺,主要包括多巴胺、血清素、酪胺、色胺等,这些芳香族单胺在生物体内是维持正常生理功能的神经递质,也是参与合成某些化合物的重要前体,还可作为药物中的活性成分参与治疗多种人类疾病,具有广阔的应用前景。作为生物合成芳香族单胺所必需的酶,有关AADCs的研究也越来越深入,基于AADCs的芳香族单胺生物合成也取得了长足进步。对几种主要AADCs进行综述,为AADCs更好应用于芳香族单胺的生物合成提供参考。     

高等植物叶绿素生物合成的研究进展

叶绿素是植物叶绿体内参与光合作用的重要色素,其功能是捕获光能并驱动电子转移到反应中心.整个叶绿素生物合成过程(L-谷氨酰-tRNA→叶绿素a→叶绿素b)需要15步反应,涉及15种酶,迄今在模式植物拟南芥中已分离到27个编码这些酶的基因,完成了以拟南芥为代表的被子植物叶绿素生物合成全部基因的克隆.本文主要对近年来国内外有关植物叶绿素的生物合成过程及相关酶基因的克隆、生物合成途径中2个关键步骤(σ-氨基酮戊酸(ALA)合成和Mg离子插入原卟啉Ⅸ的调节)、影响叶绿素生物合成的主要因素(光、温度、营养元素等),以及叶绿素生物合成相关酶的其他生物学功能等的研究进展进行综述.     

苯并恶唑嗪酮类化合物功能与生物合成研究进展

苯并恶唑嗪酮(benzoxazinoids,BXs)是植物体内一种重要的次生代谢物,因其具有防御作用和化感作用得到了广泛的关注和研究。随着基因组学及分子生物学的发展,苯并恶唑嗪酮的生物合成在分子领域的研究取得了很大的进展。介绍了苯并恶唑嗪酮概况、苯并恶唑嗪酮的功能以及苯并恶唑嗪酮生物合成参与基因及表达调控。     

植物肉桂酰辅酶A还原酶基因克隆研究进展

木质素单体合成的过程中涉及了许多酶的参与,而肉桂酰辅酶A还原酶(cinnamoyl-CoA reductase,CCR)是该过程中的一个关键酶。综述了CCR基因在植物体内的克隆、基因功能及在植物组织中的表达情况,并介绍了该基因在植物的抗病虫害和抗逆性研究、饲草和能源上的应用潜力,为进一步研究CCR基因生物学功能和利用奠定了基础。     

miR319在植物器官发育中的调控作用

microRNAs(miRNAs)是一类内源性的、21~25个碱基长度的小分子非编码RNA,它通过指导剪切或者抑制翻译等方式调节植物基因的表达,参与调控植物生长发育各个方面。大量研究表明,miR319通过靶向TCPs转录因子控制植物叶、花等器官的生长命运,并参与调控部分激素生物合成和信号传导通路,在植物发育过程中发挥重要生物学功能。文章综述了miR319在植物叶形态建成、生长发育以及叶衰老和花器官发育等过程中的重要调控作用。     

一氧化氮在植物体内的来源和功能

一氧化氮(nitric oxide,NO)是生物体内重要的活性分子。NO参与了动物体内血管松弛、神经传递及免疫防御反应等一系列生理功能而被认为是可扩散的多功能第二信使。在植物体内NO也是一种广泛存在的信号分子,参与调节了许多重要的生理过程如生长、发育、抗病防御反应、细胞程序性死亡和抗逆反应。对NO在植物体内的来源、信号转导、调节植物生长发育和对胁迫的响应方面所发挥的作用进行了综述,并讨论了其潜在的一些功能。     

Folates in plants: biosynthesis, distribution, and enhancement

Folates are crucial intermediates for a set of reactions that involve the transfer of single-carbon units (C1 metabolism). They are directly involved in the synthesis of nucleic acids, methionine, pantothenate, glycine and serine, and indirectly, through S-adenosyl methionine, in all methylation reactions. Humans cannot synthesize folates de novo. In these organisms, folate deficiency has severe effects on health and affects large population groups around the world. Because plants are the main source of dietary folates, there are great concerns to select plant food having high concentrations of folates or to engineer their folate metabolism to increase the initial amount. All these attempts rely on what we know about the metabolism of folates. During these last 10 years, the complex pathway leading to the synthesis of folates has been deciphered. Our knowledge about folate synthesis and distribution during plant growth and development also increased substantially. However, important aspects of folate metabolism remain unclear, such as catabolism, transport and regulation of the homeostasis. The aim of this review was to summarize our recent findings, to describe the few attempts reported in the literature to engineer folate level in plants, and to discuss potential strategies that could be used for enhancement.     

Synthesis and turnover of folates in plants

Folates are essential cofactors for one-carbon transfer reactions, which are central to plant metabolism. Plants synthesize folates de novo, and are key sources of dietary folate for humans. Research into plant folates therefore impacts human nutrition. Biochemical progress, the sequencing of the Arabidopsis genome, and EST databases are now painting a clear picture of the folate synthesis pathway in plants and its surprising compartmentation. Moreover, new analytical advances will help to elucidate plant folate turnover and transport, which are practically unexplored.     

Folate metabolism in plants: an Arabidopsis homolog of the mammalian mitochondrial folate transporter mediates folate import into chloroplasts

The distribution of folates in plant cells suggests a complex traffic of the vitamin between the organelles and the cytosol. The Arabidopsis thaliana protein AtFOLT1 encoded by the At5g66380 gene is the closest homolog of the mitochondrial folate transporters (MFTs) characterized in mammalian cells. AtFOLT1 belongs to the mitochondrial carrier family, but GFP-tagging experiments and Western blot analyses indicated that it is targeted to the envelope of chloroplasts. By using the glycine auxotroph Chinese hamster ovary glyB cell line, which lacks a functional MFT and is deficient in folates transport into mitochondria, we showed by complementation that AtFOLT1 functions as a folate transporter in a hamster background. Indeed, stable transfectants bearing the AtFOLT1 cDNA have enhanced levels of folates in mitochondria and can support growth in glycine-free medium. Also, the expression of AtFOLT1 in Escherichia coli allows bacterial cells to uptake exogenous folate. Disruption of the AtFOLT1 gene in Arabidopsis does not lead to phenotypic alterations in folate-sufficient or folate-deficient plants. Also, the atfolt1 null mutant contains wild-type levels of folates in chloroplasts and preserves the enzymatic capacity to catalyze folate-dependent reactions in this subcellular compartment. These findings suggest strongly that, despite many common features shared by chloroplasts and mitochondria from mammals regarding folate metabolism, the folate import mechanisms in these organelles are not equivalent: folate uptake by mammalian mitochondria is mediated by a unique transporter, whereas there are alternative routes for folate import into chloroplasts.     

Folates and Folic Acid: From Fundamental Research Toward Sustainable Health

Folates are of paramount importance in one-carbon metabolism of most organisms. Plants and microorganisms are able to synthesize folates de novo, making them the main dietary source for humans and animals, which are dependent on food or feed supplies for folates. Folate deficiency is an increasing problem in the developing, as well as in the developed regions of the world, affecting millions of people. Different strategies, such as food fortification and folic acid supplementation, remain far from accessible for the poor rural populations in developing countries. Increasing knowledge concerning folate biosynthesis, transport and catabolism does not only deepen our insight on the regulation of folate metabolism but also provides the keys towards folate enhancement through metabolic engineering in bacteria, as well as in plants. Recently, promising results were obtained using such an approach, but further fundamental research is a prerequisite to develop a practicable solution to fight folate deficiency. In parallel, progress in the development and improvement of folate analysis has been made. Here, we provide the state-of-the-art of folate biosynthesis, catabolism, and salvage. Finally, we report on progress in folate biofortification and discuss the agroeconomical aspect of biofortified crop plants.     

Culture cycle dependence of folate interconversion and related enzymes in Euglena gracilis

Folates are involved in one-carbon metabolism in which one-carbon groups of increasing reduction state (formyl, methylene and methyl) are cyclically accepted and donated by the coenzyme form of folic acid, tetrahydrofolic acid. The latter originates by reduction of dihydrofolic acid, the coenzymatically inactive form. Euglena culture cycle dependence of folate distribution in oxidized, formyl and methyl forms and of enzyme activities for folate interconversion were studied. Distribution levels of all the components examined varied widely during the culture, and many of these changes occurred in the logarithmic phase of growth. In the phase of folate synthesis, there was an appreciable delay in the conversion of oxidized to reduced forms and of formyl to methyl forms. This delay appeared to be correlated with the level of corresponding enzymes. The methyl folate peak coincided with the highest level of total cell folates, at which point a severe repression of folate synthesis began. During the last phase of exponential growth, when cell folate content was reduced to one-fifth and folates had shorter glutamate chains, the level of coenzymatically inactive and inhibitory oxidized forms increased again. The reduced efficiency of the system and the change in growth rate are discussed. The activity patterns of dihydrofolate reductase and methylene tetrahydrofolate reductase were markedly different. The peak in methylene tetrahydrofolate reductase activity coincided with the absence of oxidized folates. A regulation of folate synthesis by the level of methyl folates and of methylene tetrahydrofolate reductase synthesis by the level of oxidized forms is proposed.     

Purine biosynthesis in the domain Archaea without folates or modified folates.

The established pathway for the last two steps in purine biosynthesis, the conversion of 5-aminoimidazole-4-carboxamide ribonucleotide (ZMP) to IMP, is known to utilize 10-formyl-tetrahydrofolate as the required C1 donor cofactor. The biosynthetic conversion of ZMP to IMP in three members of the domain Archaea, Methanobacterium thermoautotrophicum deltaH, M. thermoautotrophicum Marburg, and Sulfolobus solfataricus, however, has been demonstrated to occur with only formate and ATP serving as cofactors. Thus, in these archaea, which use methanopterin (MPT) or another modified folate in place of folate as the C1 carrier coenzyme, neither folate nor a modified folate serves as a cofactor for this biosynthetic transformation. It is concluded that archaea, which function with modified folates such as MPT, are able to carry out purine biosynthesis without the involvement of folates or modified folates.     

A central role for gamma-glutamyl hydrolases in plant folate homeostasis

Most cellular folates carry a short poly-γ-glutamate tail, and this tail is believed to affect their efficacy and stability. The tail can be removed by γ-glutamyl hydrolase (GGH; EC 3.4.19.9), a vacuolar enzyme whose role in folate homeostasis remains unclear. In order to probe the function of GGH, we modulated its level of expression and subcellular location in Arabidopsis plants and tomato fruit. Three-fold overexpression of GGH in vacuoles caused extensive deglutamylation of folate polyglutamates and lowered the total folate content by approximately 40% in Arabidopsis and tomato. No such effects were seen when GGH was overexpressed to a similar extent in the cytosol. Ablation of either of the major Arabidopsis GGH genes (AtGGH1 and AtGGH2) alone did not significantly affect folate status. However, a combination of ablation of one gene plus RNA interference (RNAi)-mediated suppression of the other (which lowered total GGH activity by 99%) increased total folate content by 34%. The excess folate accumulated as polyglutamate derivatives in the vacuole. Taken together, these results suggest a model in which: (i) folates continuously enter the vacuole as polyglutamates, accumulate there, are hydrolyzed by GGH, and exit as monoglutamates; and (ii) GGH consequently has an important influence on polyglutamyl tail length and hence on folate stability and cellular folate content.     

Effects of deuterium oxide on folate metabolism in Lactobacillus casei

Various folate coenzymes and their polyglutamyl derivatives involved in 1-carbon metabolism are modulated as a result of altered physiological states and also vary with respect to growth conditions. We studied the metabolic changes in folic acid and their conjugated polyglutamyl derivatives in Lactobacillus casei cells grown in the presence of D20. A 40% decrease in methyltetrahydrofolyl polyglutamate derivatives was observed in the cells grown in media prepared with D20-depleted water (D20 content, 8-10 ppm). Chromatographic analysis of folates showed significant alterations in the formyl- and methyltetrahydrofolate derivatives and their polyglutamylation profiles. Higher amounts of oxidized folates were also present in the cells grown in D20-depleted conditions. No significant changes were observed in folates and their polyglutamate derivatives when the cells were grown in the presence of 300, 450 and 600 ppm D20. The altered folate homoestasis is attributed to changes in the metabolic adaptation of cells to D20-depleted environment.     

Subcellular localization of gamma-glutamyl carboxypeptidase and of folates.

The subcellular distributions of glutamyl carboxypeptidase, folate specific activities, and radioactive metabolites of injected [3H] folic acid were studied in rat liver. The specific activity of glutamyl carboxypeptidase in the lysosomal fraction was near or greater than four times that in the other subcellular fractions. The specific activity of folates was highest in the soluble fraction (102 ng folate/mg protein) and lowest in the microsomal fraction (22 ng folate/mg protein). Nuclear, mitochondrial, and lysosomal folates were 95% folate polyglutamates, and microsomal and soluble folates were 85--90% folate polyglutamates. Injected [3H] folic acid was initially concentrated in the microsomal fraction, as measured by 3h cpm per ng folate. Initially, injected [3H] folic acid was found converted to folate penta- and hexaglutamates in all fractions to a similar extent except in the microsomes where the percentage conversion was much less, as measured by the percentage of total 3H cpm determined to be [3H] folate penta- and hexaglutamates. At 24 h, the conversion of [3H] folates to penta- and hexaglutamates in each fraction was less than that found for the endogenous folates. Injected [3H] folic acid after 2h was found to consist of 94% reduced folates in the soluble fraction, 56% in the mitochondrial, 55% in the nuclear, 20% in the lysosomal, and 15% in the microsomal fraction.