外源咖啡酸和阿魏酸对黑莓汁中花色苷的辅色研究

为增强黑莓汁中花色苷的稳定,添加适量咖啡酸和阿魏酸到黑莓清汁中,采用可见吸收光谱和高效液相色谱-质谱研究其对黑莓花色苷的辅色作用。研究结果表明:黑莓汁中添加咖啡酸和阿魏酸显著增加了花色苷的最大吸收值(Aλmax),最大吸收波长(λmax)红移,说明咖啡酸和阿魏酸对黑莓汁中花色苷产生了辅色作用,辅色效应随时间的延长和咖啡酸、阿魏酸浓度的增加显著增强。HPLC-DAD-MS分析发现,咖啡酸辅色产生了两种新的花色苷衍生物(矢车菊素-3-O-葡萄糖苷-4-乙烯基儿茶酚和矢车菊-3-O-草酸酐酰葡萄糖苷-4-乙烯基儿茶酚),阿魏酸辅色产生了三种新的花色苷衍生物(矢车菊素-3-O-葡萄糖苷-4-乙烯基愈创木酚、矢车菊-3-O-草酸酐酰葡萄糖苷-4-乙烯基愈创木酚和矢车菊-3-O-阿拉伯糖苷-4-乙烯基愈创木酚),这些衍生物均为羟苯基-吡喃花色苷。     

紫淮山全粉喷雾冷冻干燥工艺及其特性研究

制备高品质的紫淮山全粉,有利于拓宽紫淮山的消费途径和提升产品价值。本文考察了固液比、进料流量和冻结温度对紫淮山全粉水分含量、溶解度和花色苷含量的影响,通过四因素三水平正交试验,优化了紫淮山全粉喷雾冷冻干燥工艺,并对热风干燥、真空冷冻干燥、喷雾干燥、喷雾冷冻干燥这4种干燥方式制备的紫淮山全粉理化特性和抗氧化能力进行了比较。结果表明,紫淮山冷冻喷雾干燥的最佳工艺条件为进料流量25 mL/min、固液比1∶1、冻结温度-30℃,在此条件下得到的紫淮山全粉水分含量为3. 89%、溶解度为23. 12%、花色苷含量为13. 28 mg/100 g。干燥方式对紫淮山全粉的物理性质、营养成分、活性成分和抗氧化能力的影响显著。     

丽格海棠花青素苷成分及分布对花色的影响

以红色、红心白边、粉红、玫红、黄色、黄心红边、浅粉和白色8种花色丽的格海棠花瓣为试验材料,采用目视测色法、RHSCC比色法和色差仪测定花瓣表型,通过组织切片法观察花瓣色素细胞的显微结构和分布特点,采用双光束紫外-可见光分光光度计和高效液相色谱-电喷雾离子化-质谱连用技术(HPLC-ESI-MS)测定分析花瓣中花青素苷的成分和含量,为探讨丽格海棠花色的呈色机理和花色育种提供参考。结果显示:(1)丽格海棠的明度L*随花瓣颜色变深而降低,红度a*则表现出相反趋势,红度(a*)和彩度(C*)值与明度(L*)呈显著负相关关系,且a*和C*是影响L*的主要因素。(2)红花品种花瓣色素主要分布于上表皮细胞和海绵组织中;红白花品种花瓣色素主要分布于上下表皮中,且下表皮积累量更多;粉色花和玫红花品种花瓣色素主要分布于上下表皮细胞;黄红花和粉白色花品种花瓣上表皮中含有少量色素,而黄花和白花品种花瓣几乎没有色素积累。各花色丽格海棠花瓣上表皮细胞均为圆锥形,且红花和红白花品种锥形化程度最高,它们花瓣下表皮细胞均呈扁平的长方形。(3)8个丽格海棠品种花瓣中共检测出15种花青素苷,其中10种为芍药素苷,3种为矢车菊素苷,1种为锦葵素苷,1种为飞燕草素苷,酰化花青素苷占多数;红花品种花瓣中总花青素苷含量最高,玫红花品种次之,黄花和白花品种中未检出;除粉红花品种外,其余含花青素苷的品种中芍药素苷含量最高,均占总花青素苷含量的50%以上,是花瓣的主要呈色物质。(4)丽格海棠花瓣中总花青素苷含量与其红度(a*)、彩度(C*)值呈正相关关系、与其L*值呈负相关关系。研究表明,花青素苷的积累有利于丽格海棠花瓣红色化,并影响其花瓣彩度(C*)及明度(L*);色素分布细胞数量和上表皮细胞锥形化明显影响花瓣呈色,且花瓣主要的呈色物质为芍药素苷,酰基化修饰可能影响其明度。     

紫色马铃薯花色苷稳定性研究

探讨pH、光照、温度、氧化剂、还原剂、金属离子、防腐剂对紫色马铃薯花色苷理化稳定性的影响。结果表明：紫色马铃薯花色苷只有在酸性条件下才可以稳定存在;对光、热敏感,稳定性差;氧化剂和还原剂对紫色马铃薯花色苷有较大的破坏作用;Na+、Fe2+对紫色马铃薯花色苷有破坏作用,Mg2+、Mn2+、Cu2+可起到一定辅色作用;苯甲酸钠对紫色马铃薯花色苷稳定性影响不大,抗坏血酸具有减色作用。在今后的加工或贮藏中,应尽量选择避免对紫色马铃薯花色苷具有破坏性的条件。     

遮光对地被菊花色苷含量和CmUFGT基因表达的影响

以地被菊品种‘紫重楼’为试材,设置4种光环境梯度:L0(CK,全光照)、L1(80%全光照)、L2(60%全光照)和L3(40%全光照),研究花序不同发育期遮光处理对‘紫重楼’开花过程中叶绿素含量、干重、干重比、花色苷含量、可溶性糖含量和CmUFGT基因表达量的影响,以探讨光在花色苷合成和降解过程中的作用。结果表明:(1)现蕾期、露色期遮光处理下,叶绿素a、b含量随光照强度的降低而逐渐增加,其中L3处理下叶绿素a、b含量显著高于其他处理;盛花期遮光处理下,叶绿素a、b含量随光照强度的降低呈先增后降的趋势,其中L1处理下叶绿素a、b含量极显著高于其他处理。(2)花序干重随着光照强度的降低呈下降趋势,花序干重比呈先升后降的趋势,其中L1处理下花序干重比增加。(3)现蕾期、露色期遮光处理下花色苷含量随着花序发育呈先升后降的变化趋势,盛花期遮光处理下呈下降趋势;花序发育第3、4阶段,光照越强花色苷含量越高;第7、8阶段,光照越弱花色苷含量越高。(4)遮光处理下舌状花可溶性糖含量随着花序发育呈先升后降趋势,其中L1处理下可溶性糖含量增加。(5)遮光处理极显著抑制花序发育第5阶段CmUFGT基因的表达,且表达量随着光照强度的降低而逐渐降低;现蕾期、露色期L1处理下,花序发育第3、4阶段CmUFGT基因表达量降低。研究表明,地被菊花序发育中期(第3、4阶段)轻度遮光(L1)抑制CmUFGT基因表达,促进可溶性糖含量增加,有利于花色苷的合成;花序发育后期(第7、8阶段)重度遮光(L3)有利于缓解花色苷的降解。     

耐盐紫甘薯花色苷组分分析和抗氧化性研究

利用高效液相色谱与二极管阵列检测器/电喷雾质谱联用技术研究了耐盐紫甘薯Z103中的花色苷类化合物,确定该品种含有15种花色苷,主要为被咖啡酸、阿魏酸、对羟基苯甲酸等芳香酸酰化的矢车菊苷和芍药苷,其中矢车菊素3-O-对羟基苯甲酰-槐糖苷-5-O-葡糖苷、芍药素3-O-对羟基苯甲酰-槐糖苷-5-O-葡糖苷、芍药素3-O-阿魏酰-槐糖苷-5-O-葡糖苷为首次报道;同时进一步考察了不同体系中,紫甘薯花色苷抑制脂质过氧化能力和对DPPH·、O-·2和HO·的清除作用,结果表明紫甘薯花色苷具有较强的抗氧化能力,且均具有量效关系。紫甘薯花色苷(0.4 mg/mL)对脂质体氧化的抑制率为83.24%,对DPPH·(0.20 mg/mL)、O-·2(4 mg/mL)和HO·(30μg/mL)的清除率分别为94.06%、96.62%和96.12%。     

紫甘薯花色苷色素的抑菌作用研究

本文研究了紫甘薯花色苷色素抑制大肠杆菌、金黄色葡萄球菌、啤酒酵母和黑曲霉的作用及机理。结果表明：紫甘薯花色苷色素对大肠杆菌及金黄色葡萄球菌均有抑制作用, 并与其浓度呈正相关, 而对啤酒酵母和黑曲霉无抑制作用。透射电镜观察和大肠杆菌生长曲线表明, 该色素的抑菌作用可能是通过增强细胞膜的通透性, 使细胞异常生长, 抑制对数生长期的细胞分裂, 使细胞质稀薄、细胞解体。SDS-PAGE 分析表明, 紫甘薯花色苷对大肠杆菌蛋白表达影响不明显, 未见特征性条带的消失, 仅对部分蛋白质合成量有影响。     

两个八仙花品种花色苷的提取、鉴定和理化稳定性

为优化八仙花花色苷提取条件，探究具有不同花色可调性的八仙花花色苷组分和理化稳定性差异，初步解释八仙花花色可调性存在差异的原因，该文以花色不可调的‘蒂亚娜(Tijana)’和花色可调的‘拉维布兰(Ravi Brent)’八仙花(Hydrangea macrophylla)为材料，通过L₉(3³)正交试验确定超声波法提取花色苷的最优条件，利用UPLC-Q-TOF-MS法进行花色苷组分的鉴定，分析离体条件下温度、光照、金属离子和糖类对八仙花花色苷理化稳定性的影响。结果表明：(1)花色苷提取的最优条件是‘蒂亚娜’和‘拉维布兰’的乙醇浓度分别为70%和80%,料液比均为1∶20,提取时间均为20 min。(2)二者的主要花色苷组分均为飞燕草素-3-O-葡萄糖苷。(3)八仙花花色苷在温度≤70℃暗处保存效果更好。(4)花色不可调的‘蒂亚娜’八仙花花色苷对光照、糖类和大多金属离子更稳定；只有花色可调的‘拉维布兰’八仙花花色苷加入中低浓度(10～30 mmol·L^-1)Al³⁺后由粉色变为蓝色且稳定性提高，而‘蒂亚...     

紫甘薯花色苷色素的抑菌作用研究

本文研究了紫甘薯花色苷色素抑制大肠杆菌、金黄色葡萄球菌、啤酒酵母和黑曲霉的作用及机理.结果表明:紫甘薯花色苷色素对大肠杆菌及金黄色葡萄球菌均有抑制作用,并与其浓度呈正相关,而对啤酒酵母和黑曲霉无抑制作用.透射电镜观察和大肠杆菌生长曲线表明,该色素的抑菌作用可能是通过增强细胞膜的通透性,使细胞异常生长,抑制对数生长期的细胞分裂,使细胞质稀薄、细胞解体.SDS-PAGE分析表明,紫甘薯花色苷对大肠杆菌蛋白表达影响不明显,未见特征性条带的消失,仅对部分蛋白质合成量有影响.     

黑果腺肋花楸花色苷对人皮肤成纤维细胞紫外辐射损伤的保护作用

为了探讨黑果腺肋花楸花色苷对紫外辐射所致人皮肤成纤维细胞氧化损伤的保护作用,将体外培养的人皮肤成纤维细胞分为对照组、辐射组和辐射给药组。采用MTT法检测不同浓度花色苷添加量对细胞增殖的保护作用,以选择最优添加浓度。采用化学荧光法检测细胞活性氧(ROS)含量,ELISA法检测细胞MMP-1分泌水平。结果表明:UVA辐照剂量为10 J/cm2条件下,与辐射组相比,MTT法显示花色苷添加组浓度为125μg/m L对损伤细胞增殖保护作用有极显著的提高(P0.01),同时,125μg/m L花色苷添加组能够显著降低辐射损伤后细胞ROS含量以及MMP-1分泌水平(P0.01)。由此可见,适宜浓度的黑果腺肋花楸花色苷能够降低细胞ROS含量及MMP-1分泌水平,从而对辐射损的细胞起到一定的保护作用。     

不同溶剂和保存条件对尾叶悬钩子花色素苷提取及稳定性的影响

对尾叶悬钩子(Rubus caudifolius Wuzhi)鲜果中花色素苷的提取条件、主要化学组分及pH值、温度、没食子酸和Al^3 对其颜色及稳定性的影响进行了分析探讨。结果表明,尾叶悬钩子花色素苷的主要组分可能为矢车菊素-3-葡萄糖苷;pH值和温度影响该花色素苷的色泽及其稳定性,随着pH值和温度的增加,其分解加剧,且花色素苷的分解均遵循动力学一级反应规律;添加不同浓度的Al^3 ,色素溶液的吸光值有所升高,显示出有一定的增色效应,但Al^3 和没食子酸对贮藏期间花色素苷的稳定性及色泽均无明显效果。     

Active anthocyanin degradation in <Emphasis Type="Italic">Brunfelsia calycina</Emphasis> (yesterday–today–tomorrow) flowers

Anthocyanins are the largest group of plant pigments responsible for colors ranging from red to violet and blue. The biosynthesis of anthocyanins, as part of the larger phenylpropanoid pathway, has been characterized in great detail. In contrast to the detailed molecular knowledge available on anthocyanin synthesis, very little is known about the stability and catabolism of anthocyanins in plants. In this study we present a preliminary characterization of active in planta degradation of anthocyanins, requiring novel mRNA and protein synthesis, in Brunfelsia calycina flowers. Brunfelsia is a unique system for this study, since the decrease in pigment concentration in its flowers (from dark purple to white) is extreme and rapid, and occurs at a specific and well-defined stage of flower development. Treatment of detached flowers with protein and mRNA synthesis inhibitors, at specific stages of flower development, prevented degradation. In addition, treatment of detached flowers with cytokinins delayed senescence without changing the rate of anthocyanin degradation, suggesting that degradation of anthocyanins is not part of the general senescence process of the flowers but rather a distinctive and specific pathway. Based on studies on anthocyanin degradation in wine and juices, peroxidases are reasonable candidates for the in vivo degradation. A significant increase in peroxidase activity was shown to correlate in time with the rate of anthocyanin degradation. An additional indication that oxidative enzymes are involved in the process is the fact that treatment of flowers with reducing agents, such as DTT and glutathione, caused inhibition of degradation. This study represents the first step in the elucidation of the molecular mechanism behind in vivo anthocyanin degradation in plants.     

三七块根紫色素的花色苷本质及其含量和总皂苷含量的正相关性

三七是中国云南省的"第一药材",云南文山三七是三七的道地药材。三七块根的横截面为黄白色至紫色。紫色块根约占研究块根总数的28 .21 %,其中柱鞘、内皮层、皮层或表皮为紫色。特征颜色反应和紫外——可见光谱表明:三七块根紫色素属于黄酮类化合物,可能含有酚性邻位二羟基,不含类胡萝卜素、查耳酮、噢哢、异黄酮、儿茶素。花色苷和/或其苷元花色素奠定了紫色块根着色的基础,其他的非红色的黄酮类化合物起共色素的作用。块根的平均花色苷含量和平均总皂苷含量均以纯紫色块根的为最高,其次是黄紫混合色块根的,纯黄色的最低。块根的花色苷含量差异达到极显著水平,但总皂苷含量差异却没有达到显著水平。每个块根都含有不同量的花色苷,随花色苷量的增加,块根的紫色一般逐渐明显。块根的花色苷含量与其总皂苷含量之间呈显著正相关,相关系数r=0 .355。本文可为三七块根颜色呈现的机理探索及其色素的分子结构鉴定提供参考。     

Anthocyanin inheritance and instability in purple basil (Ocimum basilicum L.)

The instability of the purple pigments (anthocyanins) in purple basil varieties (Ocimum basilicum L.) limits their use as ornamental plants and as a potential anthocyanin source. Several self-pollinated generations of all purple plants were unsuccessful in stabilizing anthocyanin expression. In this study we investigated the inheritance and stability patterns of leaf traits using the Purple Ruffles variety. The results from the complete diallele crosses indicated anthocyanin expression in vegetative tissue is controlled by two dominant genes and ruffled leaf texture is controlled by a single recessive gene. Genes controlling leaf margin and leaf base structures were tightly linked to leaf texture. Essential oil production and oil constituents in leaves did not change as a result of the reversion in color. Color stability in cuttings was affected by the environment and the location where cuttings were taken. An accumulation of secondary metabolites (apigenin, genistein, and kaempferol) in green-reverted sectors on purple leaves was detected using reverse-phase high-performance liquid chromatography (HPLC) analysis; this suggested a potential block in the anthocyanin pathway. We hypothesize the reversion mutation is occurring in an anthocyanin regulatory gene.     

紫山药色素的提取工艺及抗氧化性能研究

研究紫山药色素的最佳提取工艺及其抗氧化性能。在单因素试验的基础上,采用L9(34)正交试验法,以pH示差法测定花色苷得率为考察指标,优化了溶剂提取法提取紫山药色素的工艺参数。通过DPPH体系测定该色素清除自由基能力。试验结果表明:紫山药色素属于花色苷类物质,优化的紫山药色素提取条件为:提取温度60℃,提取时间80 min,料液比1∶30,提取溶剂为0.5%盐酸乙醇溶液,提取液花色苷含量可达2.075mg/鲜紫山药g。紫山药色素提取液清除DPPH自由基的IC50为98.14μg/mL。紫山药具有开发功能性色素的潜力。     

Linkage of the <Emphasis Type="Italic">A</Emphasis> locus for the presence of anthocyanin and <Emphasis Type="Italic">fs10.1</Emphasis>, a major fruit-shape QTL in pepper

The purple color of the foliage, flower and immature fruit of pepper ( Capsicum spp.) is a result of the accumulation of anthocyanin pigments in these tissues. The expression of anthocyanins is controlled by the incompletely dominant gene A. We have mapped A to pepper chromosome 10 in a Capsicum annuum (5226) x Capsicum chinense (PI 159234) F(2) population to a genomic region that also controls anthocyanin expression in two other Solanaceous species, tomato and potato, suggesting that variation for tissue-specific expression of anthocyanin pigments in these plants is controlled by an orthologous gene(s). We mapped an additional locus, Fc, for the purple anther filament in an F(2) population from a cross of IL 579, a C. chinense introgression line and its recurrent parent 100/63, to the same position as A, suggesting that the two loci are allelic. The two anthocyanin loci were linked to a major quantitative trait locus, fs10.1, for fruit-shape index (ratio of fruit length to fruit width), that also segregated in the F(2) populations. This finding verified the observation of Peterson in 1959 of linkage between fruit color and fruit-shape genes in a cross between round and elongated-fruited parents. The linkage relationship in pepper resembles similar linkage in potato, in which anthocyanin and tuber-shape genes were found linked to each other in a cross of round and elongated-tuber parents. It is therefore possible that the shape pattern of distinct organs such as fruit and tuber in pepper and potato is controlled by a similar gene(s).     

Ultraviolet-B-Responsive Anthocyanin Production in a Rice Cultivar Is Associated with a Specific Phase of Phenylalanine Ammonia Lyase Biosynthesis

Seedlings of 17 rice (Oryza sativa L.) cultivars were classified on the basis of anthocyanin pigmentation into three groups: an acyanic group with 9 cultivars, a moderately cyanic group with 5 cultivars, and a cyanic group with 3 cultivars. Seedlings of the cyanic group were deep purple in color, possessing copious amounts of anthocyanin in shoots. Sunlight (SL)-mediated anthocyanin and phenylalanine ammonia lyase (PAL) induction in a cyanic cultivar, purple puttu, was compared with an acyanic cultivar, black puttu. A brief exposure of dark-grown purple puttu seedlings to SL induced anthocyanin formation during a subsequent dark period with a peak at 24 h. The magnitude of SL-mediated anthocyanin induction is age dependent, the 4-d-old seedlings being the most responsive to SL. The anthocyanin induction in purple puttu seedlings is mediated exclusively by the ultraviolet-B (UV-B) component of SL. The SL-triggered anthocyanin induction was reduced by about 30% by a terminal far-red light pulse and was restored by a red light pulse, indicating the role of phytochrome in modulation of anthocyanin level. The SL-mediated induction of PAL showed two peaks, one at 4 h and the other at 12 h. Whereas the first PAL peak (4 h) was induced by phytochrome and was seen in both cultivars, the second PAL peak (12 h) was inducible by UV-B only in the cyanic purple puttu cultivar.     

菊花不同花色品种中花青素苷代谢分析

应用高效液相色谱和多级质谱联用技术（HPLC-ESI-MSn）,分析菊花（Chrysanthemum×morifolium）白色、粉色、红色、紫色、红紫色和墨色6个色系共计82个品种中花青素苷合成过程的中间产物和最终产物,发现从白色、粉色、红色、紫色、红紫色到墨色花青素苷含量快速增加,分别为4.68、111.60、366.89、543.56、1220.36和2674.95μg·g-1,不同色系间花青素苷的含量差异显著（P〈0.01）,花青素苷含量越高花色越深;墨色菊花品种中总类黄酮含量显著高于其它花色品种（P〈0.01）,其它不同色系间总类黄酮含量差异不显著（P〉0.05）;随着菊花花色变深,从柚皮素分支到圣草酚的代谢流,以及从圣草酚分支到矢车菊素苷的代谢流比例增加。花青素苷成分分析发现：菊花中只含有矢车菊素苷类化合物。根据花青素苷代谢成分分析结果绘制了菊花中花青素苷代谢路径图,即在菊花类黄酮代谢途径中只存在矢车菊素苷代谢分支途径;菊花不同色系在柚皮素和圣草酚2个关键代谢分支点上向不同方向代谢流的分配比例不同,造成花青素苷产物含量不同,导致不同花色。以上研究结果为菊花花色改良的分子育种提供了理论依据。     

花青素调节基因VlmybA2对番茄遗传转化

以小型番茄 Micro-Tom 为材料,利用农杆菌介导法导入花青素调节基因VlmybA2。对抗性筛选出的再生植株进行 GUS 组织染色和 PCR 检测,证明外源基因已经整合到 Micro-Tom 中,转基因番茄根、茎、叶脉、果皮均呈紫色,花色为黄紫嵌合。而野生型的根为白色,茎、叶脉呈绿色,果皮为红色,花为黄色。对转基因番茄的花青素含量、叶片叶绿素含量和光合速率等生理指标进行测定,花青素含量有显著增加,叶绿素含量降低,VlmybA2基因过量表达会降低植株的光合效率,但对植株正常生长影响并不显著。VlmybA2 基因既可增加抗衰老物质花青素含量,又可作为转基因植株的报告基因。     

菊花不同花色品种中花青素苷代谢分析

应用高效液相色谱和多级质谱联用技术(HPLC-ESI-MSⁿ), 分析菊花(Chrysanthemum × morifolium)白色、粉色、红色、紫色、红紫色和墨色6个色系共计82个品种中花青素苷合成过程的中间产物和最终产物, 发现从白色、粉色、红色、紫色、红紫色到墨色花青素苷含量快速增加, 分别为4.68、111.60、366.89、543.56、1 220.36和2 674.95 μg·g^–1, 不同色系间花青素苷的含量差异显著(P<0.01), 花青素苷含量越高花色越深; 墨色菊花品种中总类黄酮含量显著高于其它花色品种(P<0.01), 其它不同色系间总类黄酮含量差异不显著(P>0.05); 随着菊花花色变深, 从柚皮素分支到圣草酚的代谢流, 以及从圣草酚分支到矢车菊素苷的代谢流比例增加。花青素苷成分分析发现: 菊花中只含有矢车菊素苷类化合物。根据花青素苷代谢成分分析结果绘制了菊花中花青素苷代谢路径图, 即在菊花类黄酮代谢途径中只存在矢车菊素苷代谢分支途径;菊花不同色系在柚皮素和圣草酚2个关键代谢分支点上向不同方向代谢流的分配比例不同, 造成花青素苷产物含量不同,导致不同花色。以上研究结果为菊花花色改良的分子育种提供了理论依据。