滇金足草、凋缨菊和长喙吴萸的化学成分研究

本论文对滇金足草（Goldfussia yunnanensis）、凋缨菊（Camchaya loloana）和长喙吴萸（Evodia vestia）的化学成分进行了研究，通过色谱分离得到40个化合物。主要基于波谱数据鉴定了它们的结构，其中10个为新化合物。 1．从滇金足草地上枝叶的95%乙醇提取物中共分离鉴定了16个化合物：泽漆内酯A（1）、18-羟基泽漆内酯A（2）、18-氧代泽漆内酯A（3）、18-羟基-3-O-β-D-吡喃葡萄糖-泽漆内酯A（4）、3-O-β-D-吡喃葡萄糖-泽漆内酯A（5）、3-O-β-D-吡喃半乳糖-泽漆内酯A（6）、6-E-肉桂酰哈巴俄苷（7）、E-哈巴俄苷（8）、5，6-异亚丙二氧基哈巴俄苷（9）、β-谷甾醇（10）、β-胡萝卜苷（11）、齐墩果酸（12）、肉桂酸（13）、麦角固醇（14）、硬脂酸（15）和丁二酸（16）。其中2-7为新化合物。5，6-异亚丙二氧基哈巴俄苷（9）以人工产物形式得到。 2．从凋缨菊地上枝叶的95%乙醇提取物中分离并鉴定了13个化合物：凋缨菊内酯A~C (17-19)、1β-乙酰基凋缨菊内酯C(20)、b-谷甾醇（10）、β-胡萝卜苷（11）、羽扇豆醇（21）、桦木醇（22）、桦木酸（23）、芥子醇（24）、紫丁香苷（25）、咖啡酸（26）和熊果酸（27）。其中化合物17-20为桉叶烷内酯类新化合物。化合物17、18、20对细胞株HepG2的GI50依次为7.80、7.08、4.99 µg/mL。 3．从长喙吴萸（E. vestia）地上枝叶的95%乙醇提取物中分离并鉴定了13个化合物：佛手内酯（28）、花椒毒素（29）、异茴芹内酯（30）、七叶内酯（31）、东莨宕素（32）、瑞香素（33）、异紫花前胡内酯(34)、茵芋碱（35）、山刈碱（36）、白鲜碱（37）、黄柏酮（38）、柠檬苦素（39）和对羟基苯甲醛（40）。 4．综述了1990—2007年期间从菊科植物中发现的桉叶烷-12，6内酯的化学结构、生物活性、生物转化及化学合成方面的研究进展。 Phytochemical investigation on Goldfussia yunnanensis, Camchaya loloana, and Evodia vestia, led to the isolation of 40 compounds, 10 of which were new ones. 1. Six new compounds were isolation from 95% ethanolic extract of the aerial parts of G. yunnanensis, and identified as 18-hydroxyhelioscopinolide A (2), 18-oxohelioscopinolide A (3), 18-hydroxy-3-O-β-D-glucopyranosylhelioscopinolide A (4), 3-O-β-D-glucopyranosylhelioscopinolide A (5),3-O-β-D-Galactopyranosyl helioscopinolide A (6), 6-O-trans-cinnamoyl E-harpagoside (7). The known compounds isolated were helioscopinolide A (1), E-harpagoside A (8), 5,6-isopropylidene E-harpagoside A (9), β-sitosterol (10), β-daucosterol (11), oleanolic acid (12), cinnamic acid (13), ergosterol (14), stearic acid (15) and succinic acid (16). Compound 9 was an artifact. 2. Four new compounds, loloanolides A – C (17 - 19) and 1β-acetoxy-loloanolide C (20), were isolation from 95% ethanolic extract of the aerial parts of C. loloana. The known ones were β-sitosterol (10), β-daucosterol (11), lupeol (21), betulin (22), betulinic acid (23), sinapyl (24), syringin (25), caffeic acid (26) and ursolic acid (27). The GI50 values of compounds 17, 18 and 20 to HepG2 cell line were 7.80, 7.08 and 4.99 µg/mL, respectively. 3. Thirteen were isolated from 95% ethanolic extract of the aerial parts of E. vestia for the first time. They were determined to be bergapten (28), xanthotoxin (29), isopimpinellin (30), esculetin (31), scopoletin (32), daphnetin (33), marmesin (34), skimmianine (35), confusameline (36), dictamine (37), obacunone (38), limonin (39) and p-hydroxy phenyl aldehyde (40). 4. The structures, biological activities, biotransformation and chemical syntheses of eudesmane-12, 6-olides from the Asteraceae during 1990-2007 were reviewed.

川西青杨组(Section Tacamahaca Spach)不同种的亲缘关系分析

青杨组（Section Tacamahaca Spach）杨树是我国重要的乡土经济树种，目前对其分子遗传变异和系统进化的研究还很少，尤其是在青杨组杨树遗传资源极为丰富的川西地区，杨树的分子进化及亲缘关系的研究极为缺乏，非常不利于该树种遗传资源的开发和利用。本研究从川西地区收集了青杨（Populus cathayana）、青海杨（P. prezewalskii）、滇杨（P. yunnanensis）、康定杨（P. kangdingensis）、西南杨（P. schneideri）、小叶杨（P.simonii）和三脉青杨（P. trinervis）这7 个青杨组树种的10 个群体，利用多种分子标记手段对其种间的亲缘关系进行比较，并结合形态和地史资料进行了全面的研究和评价，得到了如下的主要研究结果： 1. SSR 和ISSR 位点变异丰富。通过10 对引物对50 个杨树个体的DNA 样品进行了SSR 分析，所有位点展现了丰富的群体间和种间的多态性，多态位点率达到了100%，每位点的等位基因数变化范围为5 ~ 17，平均为11.9 个；通过11 条ISSR 随机引物对供试的混合DNA 样品进行分析，共检测到130 个标记，其中多态性标记为119 个，多态百分率为91.5%。研究认为，SSR 单个标记能展现高水平信息，而ISSR 单个引物能探测更多数量多态性。通过两个标记的遗传距离、聚类图和PCA 分析，表明：同一种内不同群体间的同源性最高；康定杨和西南杨有较近的亲缘关系；小叶杨和三脉青杨聚合在一起，显示了其相互较近的亲缘关系；滇杨与其它杨树种可能存在着较远的亲缘关系。 2. 采用4 对选择性引物对7 个青杨组杨树种10 个群体进行AFLP 分析，总共扩增出284 个位点，其中200 个位点显示出了多态性，多态位点百分比为70.4%，平均多态带为50 条。TE-AFLP 的分析总共扩增出192 个位点，其中139 个位点显示出了多态性，多态位点百分比为72.4%，平均多态带为34.7 条。比较的结果表明AFLP、TE-AFLP 的遗传信息含量比较接近，略小于ISSR，大约仅为SSR 的1/3；但这两个基于AFLP 的标记系统的信息探察能力也远大于ISSR 和SSR 标记系统。这两个分子标记的聚类结果，显示小叶杨、三脉青杨和滇杨三个种聚为一组，其中小叶杨与三脉青杨的亲缘关系更近；其它几个杨树种聚为一类，西南杨与青杨表现出较近的亲缘关系。 3. 所有7 对cpSSR 引物中，仅有4 个叶绿体位点在种间具有多态性，而在种内群体中并不具有多态性，共检测出13 个条带，组合成了4 种不同的单倍型；对于cpDNA的5 对引物，共检测出了73 条酶切片段，其中52 条是多态带，组合成了9 种不同的单倍型；而5 对mtDNA 通用引物未能检测出多态性的条带，表现出线粒体的保守性。叶绿体的聚类分析认为，小叶杨、三脉青杨和滇杨有较近的母性起源，且依次聚合；其余四种杨树聚为一类，并且康定杨与西南杨表现出最近的亲缘关系，并依次与青杨和青海杨聚合。 4. 根据本文的分子数据，结合形态和生境分布资料分析认为：青杨组杨树种内群体间的遗传变异程度是小于种间的遗传差异，显示了与传统分类一致的结果；三脉青杨和小叶杨有很近的亲缘关系，可能拥有相同的祖先类群；滇杨与小叶杨和三脉青杨之间具有一定的亲缘关系，特别是在其母性祖先的起源上有着一定的同源性；西南杨与青杨和康定杨均保持着较近的亲缘关系，且有可能是这两个种原始祖先杂交后所形成的。 Although western Sichuan is regarded as a natural distribution and variation center forthe Section Tacahamaca of the Populus species in China, little is currently known about themajority of poplar species occurring in this region. In the present study, molecular data wereutilized to determine the genetic relationships among Populus species in Section Tacamahacain western Sichuan including P. cathayana, P. prezewalskii, P. yunnanensis, P. kangdingensis,P. schneideri, P. simonii and P.trinervis. The results are as fellows: 1. The genetic variation at SSR and ISSR loci was abundant. All the 10 SSR loci werepolymorphic, and the number of alleles per locus varied from 5 to 17 with a mean valueequaling 11.9. Based on the 11 ISSR primers, 130 clear and reproducible DNA fragmentswere generated, of which 119 (91.5%) were polymorphic. Our results reveal that single SSRlocus can present more genetic information, while more polymorphic bands can be detectedby single ISSR primer. Moreover, the genetic distance, cluster and PCA analysisdemonstrated that: a close relationship among accessions of the same species and suggestedmonophyly in P. przewalskii and P. cathayana; P. schneideri is genetically highly similar to P.kangdingensis; P. trinervis and P. simonii have a close genetic affinity; P. yunnanensis isdistinct from the other species. 2. Genetic relationships of poplar species in Section Tacamahaca from western Sichuanwere evaluated by means of AFLP and TE-AFLP. For four AFLP primer combinations, atotal of 284 bands were obtained of which 200 (70.4%) were polymorphic with the average of50 polymorphic bands. For four TE-AFLP primer combinations, a total of 192 band wereobtained of which 139 (72.4%) were polymorphic with the average of 34.7 polymorphicbands. Our results indicate that the genetic information of AFLP is similar to that ofTE-AFLP, and little less than that of ISSR, but only about 1/3 of that of SSR. However, theability of information detection of the two AFLP-based markers is much higher than that ofISSR and SSR. In addition, the cluster analysis of AFLP, TE-AFLP and combined data revealthat: P. yunnanensis, P. trinervis and P. simonii clustered together, and P. trinervis and P.simonii showed more closed affinity; the other four poplar species clustered together, P.cathayana and P. schneideri showed more closed origin especially. 3. The cpSSR analysis for seven Populus species belonging to the Section Tacamahaca.Four out of the seven analyzed chloroplast loci were polymorphic, whereas none of the lociwere polymorphic across the accessions within a species. 13 bands and 4 different kinds ofhaplotypes were reduced. Based on 5 pairs of cpDNA primers, 73 fragments (52 polymorphic)and 9 kinds of haplotypes were produced. However, none of the polymorphic was detected bythe 5 mtDNA primer pairs, revealing conservation of mtDNA region. The cluster analysis ofcpDNA revealed that: similar maternal phylogeny among P. yunnanensis, P. trinervis and P.simonii; the other four species clustered together, P. schneideri and P. kangdingensis showedmore closed maternal lineage especially. 4. Our molecular data, morphological characters and nature habitat revealed that: sameto the traditional taxonomy assignment, genetic variation within a same Populus species islower than that among Populus species in Section Tacamahaca; P. yunnanensis may share itschloroplast ancestor with P. trinervis and P. simonii; moreover, sister genetic relationship of P.trinervis and P. simonii indicated their similar origin; P. schneideri clustered with P.kangdingensis and P. cathayana, respectively, and may have derived from an ancienthybridization event involving the ancestors of the two species.

棘蛙族(Tribe Paini)精子形态结构及精巢年周期研究

棘蛙族(Tribe Paini)隶两栖纲(Amphibia)、无尾目(Anura)、蛙科(Ranidae)、叉舌蛙亚科(Dicroglossinae)，由棘蛙属(Paa)、倭蛙属(Nanorana) 和沙巴蛙属(Chaparana)构成（Dubois,1992）。由于特殊的形态特征和染色体核型，棘蛙族受到国内外学者的广泛重视和研究，但是到目前为止，棘蛙族的系统发育关系尚未明晰，族下属种的分类和归属问题还有待进一步研究和新的证据出现。本文通过光学显微镜、电子显微镜和石蜡切片对棘蛙族10 物种的精子和精巢进行研究，旨在了解棘蛙族精子的形态、量度、超微结构特征及不同季节精巢结构的变化规律，同时为棘蛙族的系统研究提供新的依据，也为棘蛙族濒危物种的保护和经济物种的繁殖提供基础资料。研究结果表明：棘蛙族各属物种精子的形态基本相似，精子整体呈线形，由头部、中片和尾部构成。精子头部呈长条状，顶体呈锥状，位于头部顶端并向前伸出，中片较长，尾部波动弯曲。棘蛙族各属物种精子量度差异较大，将各属物种精子头部、中片、尾部、头宽、尾宽的量度数据进行聚类分析，结果表明棘蛙族10 物种可分为三类：第一类包括棘侧蛙、合江棘蛙、小棘蛙、棘腹蛙和棘胸蛙，特点是精子较短，全长在72.6～103.35µm 之间；第二类包括倭蛙、高山倭蛙、腹斑倭蛙，特点是精子较长，全长在107.74～129.75µm 之间；第三类包括隆肛蛙和双团棘胸蛙，特点是精子最长，全长在145.89～165.84µm 之间。棘蛙族各属精子超微结构基本相似：精子头部由顶体、细胞核构成；中片由中心粒、线粒体构成；尾部由单根轴丝构成。精子顶体横切呈圆环状，细胞核电子密度高；线粒体为卵圆形，呈环状围绕轴丝排列，线粒体数目较多，约30层；尾部轴丝为典型的9＋2结构，即由2根中央微管和9对外周微管组成。不同季节的倭蛙精巢结构变化表明倭蛙精巢每年只有一个生精周期，生精周期始于7 月，繁殖季节从5 月到6 月，生精高峰期为9 月；根据倭蛙不同季节精巢结构的变化，可将生精周期分为3 个阶段：第一阶段从7 月到9 月，为精子形成期；第二阶段从10 月到翌年4 月，为精子的贮存阶段，也即倭蛙的冬眠期；第三阶段从5 月到6 月，为精子的排放阶段，即倭蛙的繁殖期。不同季节的隆肛蛙精巢结构变化表明5 月为隆肛蛙的繁殖高峰期。根据棘蛙族各属精子的形态、量度和超微结构特征，结合已有的棘蛙族形态学、生态学、染色体核型及系统学研究成果，本文认为：1．基于精子数据对棘蛙族的划分和基于形态学及分子系统学数据对棘蛙族的划分均有相同之处，精子形态结构可为棘蛙族的系统研究提供新的证据。2． 棘蛙族各属精子的形态、量度及超微结构不仅与蛙科其他属种有明显差异，而且在无尾类中也较为特殊，精子学研究结果支持将棘蛙族从蛙科中分离出来，归隶于叉舌蛙科的叉舌蛙亚科的系统学修正。3. 精子的顶体、细胞核、中片的形态结构及量度可作为蛙科的分类指标。On the base of unique morphological and kyrotype characters, Dubois(1992)recognized three genera Paa, Narnorana, Chaparana as tribe Paini, which is amember of Dicroglossinae, Ranidae. In present study, the sperm shape, size andultrastructure of 10 paini species were investigated through the light and electronmicroscope, and testis structure of N. pleskei and F. quadrana was also studied. Wesuppose this study could offer some spermatological evidence to phylogeny andreproduction study of tribe Paini. The results were as follows:The sperm shape of tribe paini is homologically similar, the spermatozoa arefiliform, composed of elongate head, long mid-piece and waved tail. The acrosome isapically associated with the nucleus and extend anteriorly.The sperm length of tribe paini differ remarkably among genera. Cluster for thelength of sperm head, mid-piece, tail, total length, head-width, tail-width of ten painifrogs indicated the 10 species could be separated into three groups: GroupⅠcontainsP. shini, P. robertingeri, P. spinosa, P. exilispinosa, P. boulengeri, the spermatozoa ischaracterized with short in total length, ranging from 72.6µm to 103.35µm; GroupⅡcontains N. pleskei, N. parkeri, N. ventripunctata, the spermatozoa ischaracterized with relatively long in total length, ranging from 107.74µm to129.75µm; Group Ⅲ contains F. quadrana and P. yunnanensis, the spermatozoa is characterized with longest in total length, ranging from 145.89µm to 165.84µm. thethree groups based on spermatological data is partially match the classification basedon morphological and molecular data.The ultrastructure of spermatozoa in tribe paini is also basic similar, includingacrosome vescile, nuleus of the head proper, centriole, mitochondriol of themid-pieces, axoneme of the tail. The acrosome vescle is circle in TEM transversesection, the density of nucleus is high; The mitochondrions is oval, surrounding theaxial filament with about 30 layers of mitochondria; The axoneme has the typical 9+2pattern of microtubules.The seasonal changes in testis of N. pleskei indicates it has only onespermatogenesis circle, which begin in July, the reproduction season is from May toJune, the spermatogenesis is active in September. On the base of seasonal changes intestis, the spermatogenesis circle can be separated into three stages: In stageⅠfromJuly to September, spermatids are formed; In stage Ⅱ from October to April next year,the spermatozoa are stored in testis,which is the hibernated period; In stage Ⅲ fromMay to June, mature spermatozoa were released from the testis, which is thereproduction season of N. pleskei. As to F. quadrana, reproduction is active in May.With the previous study of morphology, ecology, karyotypes and phylogenyresearch of tribe Paini, the spermatological data in present study suggests:1. The spermatological classification of tribe paini is partially consistant with themorphological and molecular classification respectively.2.The sperm morphology and ultrustructure of tribe paini is unique not only inthe family Ranida but also in Anura, which suggest the tribe paini is monophyletic andmight be transfered from the family Ranida to the family Dicroglossidae based onmolecular evidence.3. The acrosome, nuleus, shape, length and ultrastructure of mid-piece can beused as an alternative taxonomic character in Anura.

塔叶苔属(SchiffneriaSteph.)(Hepaticae)的研究

塔叶苔属(Schiffneria Steph.)建立于1894年。作者在研究中国标本时,发现一新种———Schiffneria yunnanensis C.Gao& W.Li sp.nov.。塔叶苔属的配子体为叶状体,生殖枝具茎叶返祖现象,应置于叶苔亚纲的叶状体无组织分化类群———带叶苔目(Pallaviciniales)之中。

青藏高原高海拔地区C4植物的发现

通过对青藏高原地区27°42′～40°57′N,88°93′～103°24′E海拔2210～5050m范围内采集的植物进行碳同位素分析,发现其中2种藜科和6种禾本科植物是C4植物.11个地点的4种C4植物海拔超过了3800 m,其中6个地点的3种C4植物(白草Pennisetum centrasiaticum,云南野古草Arundinella yunnanensis和固沙草Orinus thoroldii)分布在海拔4000 m以上,最高可达4520 m.分析认为在大气低CO2分压背景下,强光照提供的充足能量使C4植物能忍耐更低的温度,以及青藏高原南部降雨集中于高温季节的有利条件,可能是C4植物生长在高海拔地区的重要原因.