七种石斛花朵挥发性成分分析

为了解几种石斛属植物鲜花挥发性成分,该文利用固相微萃取(SPME)法结合GC-MS技术分析了7种石斛(含2个品种)花朵挥发性成分及其相对含量。结果表明:(1)从7种石斛(含2个品种)中共鉴定出52种挥发性化合物,包括萜烯类、酯类、芳香族化合物、含氮化合物、烷烃类、醇类和酮类等7类,其中萜烯类总相对含量最高,为83.25%～94.93%,为主要挥发性成分。(2) 7种石斛共同含有(1R)-(+)-α-蒎烯、D-柠檬烯和顺式-β-罗勒烯等3种成分,每个品种的相对含量存在差异。其中,顺式-β-罗勒烯在鼓槌石斛、细叶石斛、流苏石斛、翅梗石斛和春石斛‘H1’等5种石斛中的含量均最高,分别达到46.09%、46.40%、39.02%、65.96%和54.34%;(1R)-(+)-α-蒎烯在鼓槌石斛、流苏石斛、翅梗石斛、春石斛‘H1’和春石斛‘818’等5种石斛中的相对含量相对较高,分别为34.11%、25.61%、15.26%、21.11%和23.21%; D-柠檬烯在翅萼石斛和翅梗石斛中的含量较高,分别为16.02%和6.86%,而在其他5种石斛中的含量均较低。(3)β-蒎烯在流苏石斛和翅萼石斛中的相对含量高达19.39%和45.95%,桧烯仅在春石斛‘818’中能检测到(12.24%)。这些含量较高的成分可能为主要的香气成分或特征性香气成分。综上结果认为,7种石斛花朵挥发性成分既含有相同的成分也含有不同成分,且含量随种类的不同而不同。这些结果可为研究石斛属植物花香代谢以及产品开发等提供参考价值。     

4种石斛属植物花朵挥发性成分分析

为了解石斛属植物花朵中的挥发性成分, 利用固相微萃取(SPME)方法结合GC-MS 技术测定了鼓槌石斛、罗河石斛、细叶石斛和密花石斛盛花期的花朵挥发性成分及其相对含量。结果表明, 从4 种石斛属植物花朵中共鉴定出挥发性成分57 种, 包括酯类、萜烯类、醇类、烷类、醛类、酮类、醌类、芳香族和含氮化合物。4 种石斛花朵挥发性成分的组成和含量差异明显。鼓槌石斛和细叶石斛的主要香气成分是3-蒈烯, 相对含量分别为84.606% 和71.251%。罗河石斛挥发性成分中水杨酸甲酯相对含量最高(57.449%), 其次为D-柠檬烯(22.416%)。密花石斛花朵主要挥发性成分是2-亚甲基-4,8,8-三甲基-4-乙烯基-双环[5.2.0]壬烷(82.013%), 其次为α-法尼烯(4.699%)。这些对于香型石斛兰品种的培育和兰花精油产品开发提供了参考。     

9 种海洋硅藻挥发性成分的比较分析

采用顶空固相微萃取气相色谱一质谱联用技术,通过SIMCA．P分析软件,对硅藻门下处于生长平台后期的9种海洋硅藻的挥发性成分进行比较分析研究。结果表明：在平台后期硅藻的挥发性成分中,醛类物质的含量和种类占据了很大的优势,壬醛、2,4-辛二烯醛、2-己烯醛、2-壬烯醛、2,4-庚二烯醛等是硅藻挥发性成分的主要构成物质,十四烷、十五烷、1-十五烯、十六烷等烷烃类是硅藻中含量仅次于醛类物质的挥发性成分,3,5-辛烯基-3-酮等短链酮类和1-辛烯基-3-醇是硅藻中含量较高的酮类和醇类物质,9种硅藻中均检测二甲基硫的存在。差异性较大的挥发性物质主要有壬醛、8-十七碳烯、1-戊烯．3．酮、1-己烯-3．醇、2,6-二甲基一苯酚,它们决定了不同的硅藻有着各自不同的风味。研究结果表明这些挥发性物质对硅藻的饵料价值、养殖生物的肉质风味、水环境的异味形成有着重要意义。     

细茎石斛花朵挥发性成分分析

为了探究细茎石斛花朵释放的挥发性成分特点,该研究利用固相微萃取(SPME)法结合GC-MS技术,检测了花色为黄绿的细茎石斛花朵不同花期、不同部位的挥发性成分和相对含量,还比较了黄绿色、白色和白色带淡紫色等三种花色的挥发性成分。结果表明:花色黄绿的细茎石斛花朵挥发性化合物成分总计为59种,其中盛花期最复杂(含有41种),这些成分归属于烯类、芳香族化合物、含氮化合物、酯类、醇类和醛酮类。在不同花期检测到的挥发性成分中,(1R)-(+)-α蒎烯相对含量始终最高,保持在27%以上;始花期和盛花期释放且相对含量较高的成分有顺-芳樟醇氧化物、β-水芹烯、柠檬烯、罗勒烯、(1S-cis)-4,7-二甲基-1-(1-甲基乙基)-1,2,3,5,6,8α-六氢萘和乙酸芳樟酯,相对含量均高于5%;衣兰烯于花蕾期相对含量最高,衰落期消失。这8种化合物可能是细茎石斛花香释放的主要香气成分或特征成分。在花色黄绿的细茎石斛盛开期的两个开花部位中,花瓣的挥发性成分有27种,蕊柱17种,其中烯类物质分别占74.16%和79.06%,花瓣可能是细茎石斛主要的释香部位。三个花色的细茎石斛盛花期挥发性化合物均在40种左右,既有成分的差异又有含量的差别,其中有25种为共同含有,三个花色均是(1R)-(+)-α蒎烯相对含量最高,含量在27%左右。这表明烯类物质是影响细茎石斛花香的重要化合物,不仅对细茎石斛产品开发提供了参考,而且还为其花香基因工程育种奠定了基础。     

三白草花、叶和茎挥发性成分的比较分析

采用顶空固相微萃取提取三白草花、叶和茎中的挥发性成分,利用GC-MS对比分析三者中的挥发性成分.从三白草花、叶和茎分别鉴定出的31、22和22个成分,分别占总挥发性成分的95.64％、98.75％和98.54％.三者共有18个化学成分,其主要化合物类型是萜类(单萜和倍半萜,其中单萜含量最高),分别占总挥发性成分的92.18％、98.19％和97.74％,还含有两个芳香族化合物:枯茗醇和姜黄烯,此外,4-(1,5-二甲基己基-4-烯)环己烯-2-酮和二十一烷两个脂肪族化合物仅存在于花中,三者的主要化合物均为柠檬烯、柠檬醛(含顺式柠檬醛)、蒎烯(含α和β构型)和β-月桂烯,另外大根香叶烯D、姜黄烯、1-b-红没药烯和β-倍半水芹烯在花中的含量均高于叶和茎.叶茎中化合物种类和含量差别均不大,但与花有较大的差别.     

4种香花型石斛花朵的挥发性成分分析

为探究石斛属(Dendrobium)盛花期花朵的主要挥发性成分,采用顶空固相微萃取结合GC-MS技术对球花石斛(D. thyrsiflorum)、扭瓣石斛(D. tortile)、鼓槌石斛(D. chrysotoxum)和密花石斛(D. densiflorum)花朵的挥发性成分进行分析。结果表明,4种石斛花朵的挥发性成分共70种,包括酯类、醇类、酚类、酮类、烷类、烯类、醛类以及其他等8类,其中烯类总含量最高,为主要挥发性成分。球花和密花石斛的主要香气成分为β-石竹烯,相对含量分别为0.46和6.91μg/(g·h);而扭瓣石斛为醋酸辛酯[6.11μg/(g·h)];鼓槌石斛为β-罗勒烯[5.23μg/(g·h)]。该研究有利于评价和筛选有价值的芳香石斛兰种质资源,为香型石斛兰品种培育和兰花精油的开发利用提供参考。     

酶法提取铁皮石斛多糖工艺优化及对挥发性成分的影响研究

铁皮石斛具有重要的药用价值,但其资源有限,因此对其充分开发和利用具有重要的意义。本文利用α-L-鼠李糖苷酶辅助提取铁皮石斛多糖,通过对酶解温度、酶解时间及加酶量三个因素进行优化,提高铁皮石斛多糖提取率;结果显示,在酶解温度为40℃、酶解时间为1 h、加酶量为2.5%时,多糖提取率为38.4%,而不加酶处理多糖提取率仅为21.7%,酶法处理大大增加了铁皮石斛的多糖提取率。同时,运用顶空固相微萃取技术结合气相色谱质谱联用仪(HS-SPME-GC-MS)分析比较α-L-鼠李糖苷酶对铁皮石斛挥发性成分的影响;GC-MS分析表明,铁皮石斛加酶处理前后共发现31种挥发性成分,主要成分均为己醛、1-辛烯-3-醇、异薄荷醇和3-辛烯-2-酮,并且醛类化合物在加酶处理前后的样品中相对含量均最高,且加酶处理后产生6种新的挥发性成分。该研究结果表明α-L-鼠李糖苷酶的使用可显著增加对铁皮石斛多糖提取率,并为铁皮石斛挥发性成分的研究和开发利用提供一定的参考依据。     

不同品种番石榴花的挥发性成分分析

为探究番石榴(Psidium guajava)花挥发性成分组成,采用顶空/气相色谱-质谱联用技术对10个番石榴品种(‘翠玉’、‘帝王’、‘本土’、‘红叶’、‘粉红蜜’、‘珍珠’、‘西瓜’、‘水蜜’、‘木瓜’和‘红宝石’)花的挥发性成分进行鉴定分析。结果表明,10个品种共检出相对含量在0.1%以上的挥发性成分43种,包含共有成分10种,以萜烯类化合物(89.77%～97.40%)为主。β-石竹烯、β-罗勒烯、桉叶油醇和D-柠檬烯为花主要挥发性成分。影响品种间挥发性成分差异的成分主要有7种,分别为α-蒎烯、β-罗勒烯、D-柠檬烯、3-蒈烯、香树烯、β-长叶蒎烯和1-异丙基-4,7-二甲基-1,2,3,5,6,8a-六氢萘。按照香气相似性,‘翠玉’和‘帝王’归为一类,‘水蜜’和‘本土’归为一类,‘粉红蜜’、‘西瓜’、‘红叶’、‘木瓜’和‘红宝石’归为一类,‘珍珠’为单独一类。不同品种番石榴花挥发性成分存在相似性和差异性,为番石榴花混合采摘及后期个性化开发利用提供理论基础。     

七种秋石斛鲜花挥发性成分差异性分析

为查明秋石斛不同品种关键赋香成分,利用固相微萃取(SPME)方法结合GC-MS技术,测定了秋石斛5个具香气的品种,即绿天使(Dendrobium Hand Green)、日出2号(Dendrobium Burana Sunrise No.2)、白花607(Dendrobium K.B.White 607)、紫背256(Dendrobium Blue Sapphine 256)、魅力(Dendrobium Burana Charming)以及2个不具香气的品种,即红牛(Dendrobium Red Bull)、三亚阳光(Dendrobium Sunya Sunshine)盛花期的花朵挥发性成分及其相对含量。结果表明:共鉴定出45种挥发性化合物,其中萜烯类34种、芳香族化合物8种、酯类3种,5种具香气的秋石斛花朵所含挥发性成分绝大部分都是萜烯类,萜烯类对秋石斛的花香起着重要的作用。通过比较发现,5种具香气秋石斛的主要赋香成分为3-蒈烯、芳樟醇、α-可巴烯和α-法尼烯,不同品种挥发性成分的组成和含量明显不同。绿天使和日出2号的主要香气成分是3-蒈烯,相对含量分别为59.343%和77.775%,但日出2号中的释放率约为绿天使的3倍;白花607主要香气成分为3-蒈烯(29.170%)、α-可巴烯(17.660%)、芳樟醇(10.990%);紫背256中α-法尼烯相对含量最高(42.310%);魅力中主要香气成分是α-可巴烯(33.648%),邻苯二甲酸二异丁酯(13.866%)为其次。2个不具香气品种中鉴定出化合物较少,主要挥发性成分释放率较小;红牛主要挥发性成分是胡莫柳酯(28.118%),三亚阳光是异丁子香酚(27.529%)。这些主要挥发性成分对不同品种秋石斛花的特有香味起决定性作用,且大部分已被广泛应用于香精香料,医药,日化等产品中。该研究结果为香型秋石斛产品开发及品种的培育提供了参考。     

模拟氮沉降对紫苏叶挥发油主要成分的影响

我国为世界三大高氮沉降区之一,氮沉降严重影响了植物生长发育。该研究采用喷施硝酸铵(NH4NO3)模拟氮沉降,分析了不同浓度氮沉降作用下紫苏叶中紫苏醛、D-柠檬烯、α-蒎烯等3种挥发油成分的变化规律。结果表明:随喷施氮盐浓度不断提高,紫苏叶挥发油的3种主要成分含量均有显著下降趋势;氮盐浓度升至0.044 mol·L~-1时,紫苏醛、D-柠檬烯、α-蒎烯的含量降至最低,之后趋于稳定;氮盐浓度对3种挥发油成分含量的比例也有影响;不同氮盐浓度处理下,3种挥发油成分的变异系数不同,紫苏醛的变异系数为0.692 9,D-柠檬烯的变异系数为0.460 1,而α-蒎烯的变异系数为0.271 6,即紫苏醛含量变化最大,α-蒎烯含量最为稳定。大气氮沉降浓度对紫苏叶挥发油主要成分含量有显著影响,随氮盐浓度不断提高,紫苏醛、D-柠檬烯、α-蒎烯等3种挥发油成分含量呈降低趋势,尤以紫苏醛含量的降低最为剧烈。氮沉降增加对紫苏叶有效成分含量有降低的作用。     

Coccystes undoxylophus

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Ester production in E. coli and C. acetobutylicum

Genetic engineering has improved the product yield of a variety of compounds by overexpressing, inactivating, or introducing new genes in microbial systems. The production of flavor-enhancing ester compounds is an emerging area of heterologous gene expression for desired product yield in Escherichia coli. Isoamyl acetate, butyl acetate, ethyl acetate, and butyl butyrate are reported here to be produced by expressing Saccharomyces cerevisiae genes ATF1 or ATF2 and the strawberry gene SAAT in E. coli when the appropriate substrates are provided. Increasing the concentration of alcohol added to the reaction generally resulted in increased ester production. ATF1 expression was found to produce more isoamyl acetate and butyl acetate than ATF2 expression or SAAT expression in the strains and culture conditions examined. Additionally, SAAT expression resulted in greater isoamyl acetate and butyl acetate production than ATF2 expression. Butyl butyrate is produced by cell-free extracts of E. coli harboring SAAT but not ATF1 or ATF2.     

UeberAquila pennata undminuta

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Aquila pennata undminuta

Ohne Zusammenfassung     

Prosthecium species with Stegonsporium anamorphs on Acer

Data from microscopic morphology, single-spore cultures, and DNA analyses of teleomorphs and anamorphs support the recognition of five species of Prosthecium with Stegonsporium anamorphs on Acer: P. acerinum sp. nov., the teleomorph of S. acerinum; P. acerophilum comb. nov., formerly known as Dictyoporthe acerophila; P. galeatum comb. nov., originally described as Massaria galeata; P. opalus sp. nov.; and P. pyriforme sp. nov., the teleomorph of S. pyriforme s. str. The morphology of both type specimens and freshly collected material was investigated. The teleomorphs have brown ellipsoidal ascospores with five distosepta and often a longitudinal distoseptum. The anamorphs of all species described here belong to Stegonsporium; their connection to the Prosthecium teleomorphs was demonstrated by morphology and DNA sequences of single spore cultures derived from both ascospores and conidia. The anamorphs and teleomorphs of all five Prosthecium species are described and illustrated by LM images, and a key to these species is provided. As perceived from this work, S. pyriforme is restricted to Europe and does not occur in North America, whereas S. acerinum is restricted to North America, not found in Europe. The host associations given in the literature are revised and evidence is provided that only A. opalus, A. pseudoplatanus, and A. saccharum are confirmed hosts of Prosthecium with Stegonsporium anamorphs. Molecular phylogenetic analyses of tef1, ITS rDNA, and partial nuLSU rDNA sequences confirm that the species with Stegonsporium anamorphs are closely related to P. ellipsosporum, the generic type species. Stilbospora macrosperma is confirmed as the anamorph of P. ellipsosporum by DNA data of single spore isolates obtained from both ascospores and conidia.     

Chemical composition, in situ ruminal degradability and post-ruminal disappearance of dry matter and crude protein from the halophytic plants Kochia scoparia, Atriplex dimorphostegia, Suaeda arcuata and Gamanthus gamacarpus

Samples of Kochia (K. scoparia), Atriplex (A. dimorphostegia), Suaeda (S. arcuata) and Gamanthus (G. gamacarpus) were collected and analyzed for chemical composition including crude protein (CP), ether extract (EE), ash, neutral detergent fiber (NDFom), acid detergent fiber (ADFom), non-protein N (NPN), Ca, P, Na, K, Cl, Mg, Fe, Cu and Se. In addition, in situ ruminal degradability and post-ruminal disappearance of dry matter (DM) and CP of the samples using a mobile bag technique were determined. Results indicate that the chemical composition of Kochia and Atriplex was notably different from those of Suaeda and Gamanthus. All of these halophytic plants had high concentrations of Na, K, Cl, Cu and Se, and low levels of Ca, P and Mg. The rapidly degradable fractions of DM and CP (g/g) of Kochia (0.31 and 0.35, respectively) and Atriplex (0.39 and 0.50, respectively) were lower than for Suaeda (0.53 and 0.55, respectively) and Gamanthus (0.56 and 0.66, respectively). Ruminal DM and CP disappearance of Kochia (444 and 517 g/kg, respectively) and Atriplex (472 and 529 g/kg, respectively) were lower (P<0.05) than those of Suaeda (553 and 577 g/kg, respectively) and Gamanthus (663 and 677 g/kg, respectively) (P<0.05) using the mobile bag technique. Suaeda had the lowest (P<0.05) NDFom and ADFom disappearance (214 and 232 g/kg, respectively) in the rumen. Kochia scoparia and Atriplex dimorphostegia have more beneficial chemical nutritive components and digestible values versus Suaeda arcuata and Gamanthus gamacarpus.     

Presence of Rhizobium Etli bv . Phaseoli and Rhizobium Gallicum bv . Gallicum in Egyptian Soils

Seven bean rhizobial strains EBRI 2, 3, 21, 24, 26, 27 and 29 identified as Rhizobium etli, and EBRI 32 identified as Rhizobium gallicum, isolated from Egyptian soils and which nodulated Phaseolus vulgaris efficiently, were subjected to hybridization with a nifH probe in order to estimate the copy number of this gene. Seven strains (EBRI 2, 3, 21, 24, 26, 27 and 29) which were only able to nodulate Phaseolus vulgaris, contained three copies of the nifH gene, consistent with their identification as Rhizobium etli bv. phaseoli. Only one strain (EBRI 32) which nodulated both Phaseolus vulgaris and Leucaena leucocephala, had one copy of nifH gene. This confirmed the classification of this strain as Rhizobium gallicum bv. gallicum.     

Flavonoids of Astilbe and Rodgersia compared to Aruncus

The flavonoid profiles of Astilbe (four taxa studied) and Rodgersia (two taxa studied) are based on simple flavonol glycosides. Astilbe has 3-O-mono-, 3-O-di-, and 3-O-triglycosides of kaempferol, quercetin, and myricetin, while Rodgersia has only mono- and diglycosides of kaempferol and quercetin. Astilbe×arendsii was also shown to accumulate dihydrochalcone glycosides. The flavonoid profile of Rodgersia is the simplest recorded so far in the herbaceous Saxifragaceae. The flavonoids of two species of Aruncus were shown to be based upon kaempferol and quercetin 3-O-mono- and 3-O-diglycosides. One of the species also exhibited an eriodictyol glycoside. The triglycoside differences were not considered important, but the differences in myricetin occurrences were taken as evidence against derivation of Saxifragaceae from an Aruncus-like ancestor. Should such an event be proposed, however, serious consideration would have to be given to the current pattern of myricetin occurrence in the two families.