半蒴苣苔属植物染色体制片优化及染色体数目和倍性研究

染色体数目和倍性是系统与进化生物学和遗传学研究中十分重要的基础信息。为探索半蒴苣苔属染色体制片的适宜条件以及染色体数目的进化模式及其与物种的进化关系，该研究基于半蒴苣苔属染色体数目的进化历史，并根据该属植物具有叶片扦插繁殖的特性，采用叶片水培生根法获取半蒴苣苔(Hemiboea subcapitata)、弄岗半蒴苣苔(H.longgangensis)、龙州半蒴苣苔(H.longzhouensis)、江西半蒴苣苔(H.subacaulis var.jiangxiensis)、华南半蒴苣苔(H.follicularis)和永福半蒴苣苔(H.yongfuensis)6种植物的根尖材料，分析不同实验条件对染色体制片效果的影响，对染色体制片实验的条件进行优化及染色体计数，结果表明：(1)9:30—10:00取材，解离10 min以及染色15 min为半蒴苣苔属染色体制片的适宜条件。(2)上述6种半蒴苣苔属植物均为二倍体，染色体数目均为32(2n=2x=32)。(3)除个别物种染色体数目有变化以外，该属大部分物种染色体数目可能为2n=2x=32且染色体数目变化可能是非整倍化的作用，与物种进化没有明...     

石山苣苔属四种(含一变种)植物的染色体数目和倍性研究

石山苣苔属(苦苣苔科)约41种,主要分布于我国西南石灰岩地区。到目前为止,仅其中四种的染色体数目被研究和报道,其余绝大多数物种的染色体数目和倍性尚不清楚,染色体数目和倍性在该属及其姐妹属报春苣苔属中的演变历史及其对两属物种多样性分化的影响亦不清楚。该文以叶片水培生根法获取的四种(含一变种)石山苣苔属植物 [即石山苣苔原变种(Petrocodon dealbatus var. dealbatus)、齿缘石山苣苔(Petrocodon dealbatus var. denticulatus)、弄岗石山苣苔(Petrocodon longangensis)、石山苣苔未定名种(Petrocodon sp.)]的根尖细胞为材料开展染色体实验,探索了多种不同的实验条件对染色体制片效果的影响并获取染色体数目,在石山苣苔属和报春苣苔属的系统树上追踪了染色体数目和倍性的演变历史,同时探讨染色体数目尤其是倍性变化是否对两属物种多样性分化存在影响。结果表明:(1)长度为1～1.5 cm的根尖,0.002 mol·L^-1 8-羟基喹啉溶液预处理5 h,解离4 min为较适宜的染色体制备条件。(2)四种(含一变种)石山苣苔属植物染色体数目一致,均为二倍体(2n=2x=36)。(3)两属之间及两属各自的最近共同祖先染色体数目尚不能确定,除个别物种染色体条数或倍性有变化以外,其余已知染色体数目的物种均为2n=2x=36,在两属中高度一致,石山苣苔属与报春苣苔属物种多样性分化尤其两属物种多样性巨大差异与染色体数目和基因组倍性变化无关。综上结果为石山苣苔属植物及其近缘类群染色体制备提供了参考,也为进一步对该类群的分类、系统演化和物种形成等方面的研究提供了基础数据和启示。     

广西苦苣苔科四种植物的染色体数目报道

首次报道了产于广西的苦苣苔科(Gesneriaceae)4属4种植物的染色体数目。其中,(1)单座苣苔属(Metabriggsia):单座苣苔(M.ovalifolia)的染色体数目2n=24;(2)异裂苣苔属(Pseudochirita):异裂苣苔(P.guangxiensis)的染色体数目为2n=28;(3)长蒴苣苔属(Didymocarpus):东南长蒴苣苔(D.hancei)的染色体数目为2n=20;(4)唇柱苣苔属(Chirita):弄岗唇柱苣苔(Ch.longgangensis)的染色体数目为2n=28。4种植物的染色体大多数为小型染色体。     

云南十种苦苣苔科植物的染色体数目报道

首次报道了产于云南的苦苣苔科Gesneriaceae2族7属10种植物的染色体数目。其中,1）芒毛苣苔属Aeschynanthus 2种：显苞芒毛苣苔A.bracteatus的染色体数目为2n=32,黄杨叶芒毛苣苔A.buxifolius2个居群的染色体数目不同,金平居群为2n=32,可能为二倍体,屏边居群的染色体数目为2n=64,可能为四倍体。2）吊石苣苔属Lysionotus 1种：吊石苣苔L.pauciflorus为2n=32。3）珊瑚苣苔属Corallodiscus 1种：石胆草 C.flabellatus的染色体数目为2n=40。4）唇柱苣苔属Chirita3种：圆叶唇柱苣苔Ch.dielsii,大叶唇柱苣苔Ch.macrophylla和美丽唇柱苣苔Ch.speciosa的染色体数目均为2n=18。5）半蒴苣苔属Hemiboea 1种：贵州半蒴苣苔H.cavaleriei为2n=32。6）马铃苣苔属Oreocharis 1种：黄马铃苣苔O.aurea为2n=34;7）石蝴蝶属Petrocosmea1种：髯毛胡蝶P.barbata为2n=32。     

广义报春苣苔属 (苦苣苔科) 的染色体新计数及其分类学意义

报道了广义报春苣苔属14种3变种和7个未定名种的染色体数目,并对其近缘属——广义石山苣苔属的3个种也进行了细胞学研究。结合最近的分类处理和系统发育假设,对所得结果和以前发表的染色体数据进行了综合分析, 结果表明：广义报春苣苔属的染色体数目为2n=36,基数为x=18,表现出高度稳定性。染色体相对较小,以中间着丝粒和亚中间着丝粒染色体为主。尽管一些类群的染色体大小之间存在微小差异,但是染色体形态的均一性和染色体数目的一致性有力地支持分子系统学的研究结果。另外,相同的染色体数目及相似的染色体形态也表明广义报春苣苔属和广义石山苣苔属的亲缘关系较近,与分子系统学的结果一致。     

广义报春苣苔属（苦苣苔科）的染色体新计数及其分类学意义

报道了广义报春苣苔属14种3变种和7个未定名种的染色体数目,并对其近缘属-广义石山苣苔属的3个种也进行了细胞学研究。结合最近的分类处理和系统发育假设,对所得结果和以前发表的染色体数据进行了综合分析,结果表明：广义报春苣苔属的染色体数目为2n=36,基数为x=18,表现出高度稳定性。染色体相对较小,以中间着丝粒和亚中间着丝粒染色体为主。尽管一些类群的染色体大小之间存在微小差异,但是染色体形态的均一性和染色体数目的一致性有力地支持分子系统学的研究结果。另外．相同的染色体数目及相似的染色体形态也表明广义报春苣苔属和广义石山苣苔属的亲缘关系较近,与分子系统学的结果一致。     

单种属弥勒苣苔属系统位置研究 基于分子和细胞学数据

弥勒苣苔属是苦苣苔科的单种属,仅分布于中国西南部。为探讨弥勒苣苔在苦苣苔亚科中的系统位置,我们选择了苦苣苔亚科116个类群,外类群为苦苣苔亚科以外的7个物种。用最大简约法（MP）和贝叶斯分析（BI）,对以上类群的核基因ITS以及两个叶绿体基因trnL-F、atpB-rbcL数据进行了独立和联合分析。在三个片段联合分析的结果中,弥勒苣苔与马铃苣苔属、后蕊苣苔属、金盏苣苔属、直瓣苣苔属以及川鄂粗筒苣苔构成一个强烈支持的分枝。MP树中,此分枝为并系,而在BI分析中,弥勒苣苔与川鄂粗筒苣苔、直瓣苣苔属互为姐妹类群。同时,第一次报道了弥勒苣苔的染色体数目（2n=34）。根据前人报道,马铃苣苔属、后蕊苣苔属、粗筒苣苔属和直瓣苣苔属的染色体数目同为2n=34,这进一步支持我们的分子系统发育分析。     

单种属弥勒苣苔属系统位置研究：基于分子和细胞学数据

弥勒苣苔属是苦苣苔科的单种属,仅分布于中国西南部。为探讨弥勒苣苔在苦苣苔亚科中的系统位置,我们选择了苦苣苔亚科116个类群,外类群为苦苣苔亚科以外的7个物种。用最大简约法（MP）和贝叶斯分析（BI）,对以上类群的核基因ITS以及两个叶绿体基因trnL-F、atpB-rbcL数据进行了独立和联合分析。在三个片段联合分析的结果中,弥勒苣苔与马铃苣苔属、后蕊苣苔属、金盏苣苔属、直瓣苣苔属以及川鄂粗筒苣苔构成一个强烈支持的分枝。MP树中,此分枝为并系,而在BI分析中,弥勒苣苔与川鄂粗筒苣苔、直瓣苣苔属互为姐妹类群。同时,第一次报道了弥勒苣苔的染色体数目（2n=34）。根据前人报道,马铃苣苔属、后蕊苣苔属、粗筒苣苔属和直瓣苣苔属的染色体数目同为2n=34,这进一步支持我们的分子系统发育分析。     

金盏苣苔属(苦苣苔科)的第二次校订

金盏苣苔属(Isometrum Craib)属于苦苣苔亚科(Cyrtandroideae)长蒴苣苔族(Didymocarpcae),是由W.G.Craib 1919根据I.farreri Craib建立的,同年他又把Didissandra glandulosa Batalin置于该属,1960年B.L.Burtt又把Didi-sandra Clarke中的4个种(即:D.prumuliflora Batalim,D.giraldii Diels,D.fargesii Franch.和D.leucantha Diels)移入该属。作者在编写中国植物志苦苣苔     

钟冠报春苣苔(苦苣苔科)的分类鉴定

原唇柱苣苔属(Chirita Buch.-Ham. ex D. Don)为一个人为界定的属, 2011年在分子系统学研究的基础上对该属及其近缘属开展了系统发育重建工作,其中绝大部分的原唇柱苣苔属唇柱苣苔组(Sect. Gibbosaccus C. B. Clark)的物种被并入了广义报春苣苔属(Primulina Hance)。然而,由于历史原因和早期经典分类学在研究方法上的局限性以及对现报春苣苔属部分物种的营养器官与生殖器官的认知不够,该属下一些物种的分类仍存在一些问题,亟待深入研究。比如,在对中国和越南分布的苦苣苔科植物开展研究的过程中,作者发现两个报春苣苔属的物种——广布于中国西南和华南直至中南半岛中部的钟冠报春苣苔[Primulina swinglei(Merr.)Mich. Möller & A. Weber]命名人和原被认为是中国与广西特有种的疏花报春苣苔[P. laxiflora(W. T. Wang)Yin. Z. Wang]之间的鉴定存在分类学问题,需要进一步厘清两者之间的关系。该文对这两个物种进行了形态比较,同时通过对这两种植物的原始描述对比、植物标本检查、栽培观察以及野外实地观察,确定疏花报春苣苔是钟冠报春苣苔的异名。此外,还明确了钟冠报春苣苔的后选指定模式标本。     

苦苣苔科镜像花的多样性及演化

泛热带分布的苦苣苔科(Gesneriaceae)在我国南方具有极高的物种丰富度与特有率,花部特征变化丰富,是研究物种形成与适应演化的代表类群。镜像花(mirror-image flowers)是极为特化的传粉系统,在苦苣苔科中出现了较多的不同类型,可能与苦苣苔科物种多样性形成与维持有关。该研究总结与分析了苦苣苔科镜像花的类型多样性以及系统分布与适应演化等,讨论了镜像花对苦苣苔科物种形成与维持的积极意义。结果表明:镜像花仅分布在亚洲和非洲的苦苣苔亚科(Didymocarpoideae)的7个属,在历史上就至少发生了5次独立起源。长冠苣苔属(Rhabdothamnopsis)、南洋苣苔属(Henckelia)及长蒴苣苔属(Didymocarpus)镜像花的花柱与可育雄蕊分别向左、右两侧偏转,形成互补镜像花;蛛毛苣苔属(Paraboea)、喜鹊苣苔属(Ornithoboea)、非洲堇属(Saintpaulia)镜像花缺乏与花柱对应侧偏的可育雄蕊(非互补镜像花);而海角苣苔属(Streptocarpus)直立堇兰亚属(subg.Streptocarpella Engler)则同时出现了互补、非互补镜像花。不同于其他被子植物(离瓣花、缺乏花冠筒),苦苣苔科中的镜像花大多伴随着明显的花冠筒、内藏的雄蕊、合生的花药,以非互补镜像花为主;传粉者以小型的无垫蜂(Amegilla spp.)和熊蜂(Bombus spp.)为主。这些特殊的花部综合征与特化的传粉机制,提高了传粉精确性,可能促进了传粉隔离与物种适应辐射。今后的一个研究重点应通过分子系统发育方法,进一步揭示苦苣苔亚科互补与非互补镜像花的进化顺序及其在物种分化与长距离扩散过程中的可能作用。     

披碱草属与大麦属系统关系的研究

禾本科中,披碱草属Elymus L.为多倍体属,约含150余种;大麦属Hordeum L.具二倍体和多倍体,约有40余种,该两属均广泛地分布于全球温带地区。该两属,尤其是披碱草属的系统分类较为困难。基于形态学的传统研究认为这两个属的系统关系较远,而细胞学研究的资料却表明,披碱草属的H染色体组起源于大麦属。笔者对来源不同的披碱草属和大麦属的物种进行了远缘杂交,并对其属间杂种F1的减数分裂中期I染色体配对行为进行了分析。结果表明,若以披碱草属作母本,该两属有相对较高的杂交亲合力,通过对杂种幼胚进行分割和离体培养,也能获得杂种F1植株。属间杂种植株的形态介于双亲之间,但更接近于披碱草属,杂种的生殖器官发育不健全,而且所有的杂种F1均完全不育。细胞学的观察结果表明,这两个属间的杂种F1通常具有较低的减数分裂中期I染色体配对数,但有较大的变异。通过笔者的工作及掌握的形态学和细胞学的资料分析认为：披碱草属和大麦属的亲缘关系较为复杂,不能一概而论。含H染色体组的披碱草属和大麦属物种有着较近的亲缘关系,但这两个属中所含的H染色体组已产生了程度不同的分化;不含H染色体组的披碱草属及大麦属的物种具有较远的亲缘关系。     

Banded karyotypes of 20 Papionini species reveal no necessary correlation with speciation

The G-banded karyotypes of 20 species of the tribe Papionini are remarkably similar, and the amount of phylogenetic interpretation permitted is limited. The genera Mandrillus and Cercocebus may be linked by a derived chromosome 10. T. gelada may be linked to the macaques by chromosome 2. Chromosome 5, which differs in M. fascicularis, makes this species an unlikely ancestor of the Sulawesi (Celebes) macaques. An alternate hypothesis, which takes into consideration the possibility that ancestral populations may be polymorphic for these chromosome variants, suggests that different chromosome variants have become fixed in different lines. These chromosomes would therefore not reflect phylogenetic relations. In the Papionini the karyotype has not played a major role in diversification and speciation.     

Evolutionary trends in Iridaceae: new cytogenetic findings from the New World

With the present work, we aim to provide a better understanding of chromosome evolutionary trends among southern Brazilian species of Iridoideae. Chromosome numbers and genome sizes were determined for 21 and 22 species belonging to eight genera of Tigridieae and two genera of Trimezieae, respectively. The chromosome numbers of nine species belonging to five genera are reported here for the first time. Analyses of meiotic behaviour, tetrad normality and pollen viability in 14 species revealed regular meiosis and high meiotic indexes and pollen viability (> 90%). The chromosome data obtained here and compiled from the literature were plotted onto a phylogenetic framework to identify major events of chromosome rearrangements across the phylogenetic tree of Iridoideae. Following this approach, we propose that the ancestral base chromosome number for Iridoideae is x = 8 and that polyploidy and dysploidy events have occurred throughout evolution. Despite the variation in chromosome numbers observed in Tigridieae and Trimezieae, for these two tribes our data provide support for an ancestral base number of x = 7, largely conserved in Tigridieae, but a polyploidy event may have occurred prior to the diversification of Trimezieae, giving rise to a base number of x₂ = 14 (detected by maximum‐parsimony using haploid number and maximum likelihood). In Tigridieae, polyploid cytotypes were commonly observed (2x, 4x, 6x and 8x), whereas in Trimezieae, dysploidy seems to have been the most important event. This feature is reflected in the genome size, which varied greatly among species of Iridoideae, 4.2‐fold in Tigridieae and 1.5‐fold in Trimezieae. Although no clear difference was observed among the genome sizes of Tigridieae and Trimezieae, an important distinction was observed between these two tribes and Sisyrinchieae, with the latter possessing the smallest genome sizes in Iridoideae. © 2014 The Linnean Society of London, Botanical Journal of the Linnean Society, 2014, 177 , 27–49.     

CHROMOSOME NUMBERS IN COMPOSITAE. III. SENECIONEAE

Ornduff , Robert (Duke U., Durham, N. C), Peter H. Raven , Donald W. Kyhos , and A. R. Kruckeberg . Chromosome numbers in Compositae. III. Senecioneae. Amer. Jour. Bot. 50(2): 131–139. Illus. 1963.—Chromosome counts are reported for 75 taxa of tribe Senecioneae (Compcsitae) and are listed with a generic summary of previous counts in the tribe. First counts are reported for Bedfordia, Crocidium, Dimeresia, Gamolepis, Lepidospartum, Luina, Peucephyllum, Telradymia, and the first definite count recorded for Euryops. New numbers are added to those previously known in Arnica and Psathyrotes. Intraspecific differences in ploidy-level are reported in 4 North American species of Senecio. Although chromosome numbers are useful as an aid in delimiting some genera of Senecioneae, they are of little use in circumscribing genera peripheral to Senecio, primarily because of the great range of chromosome numbers of that genus. Chromosome numbers support suggestions based on morphological considerations that genera such as Crocidium and Dimeresia do not belong in Senecioneae, whereas chromosome number and morphology of the plants virtually prohibit the removal of such genera as Peucephyllum, Lepidospartum, and Telradymia from Senecioneae, despite the suggestions of several recent authors. It is proposed that the base number for the tribe is 10 and that the tribe originated in the Old World, with subsequent widespread migration and diversification.     

Does chromosome number count? Mapping karyological knowledge on Italian flora in a phylogenetic framework

Italian vascular flora is highly representative of the Euro-Mediterranean area, because the region includes high mountain territories, temperate areas, and regions dominated by the Mediterranean climate. Chromosome number information about the Italian flora stored in the online database Chrobase.it includes 6,756 records, referable to 3,539 cytotypes and 2,785 accepted species and subspecies (approx. 35% of the national flora). Appropriate queries to Chrobase.it enabled us to map chromosome numbers, at order rank, in a robust phylogenetic framework, derived from APGIII and other recent phylogenetic studies on vascular plants. Similar work was conducted for selected families and genera. Chromosome number data were available for 41 out of 80 vascular plant orders (51%) currently recognized world-wide and 107 out of 428 families (25%), represented by 661 genera (4.5%). The large number of records enabled us to compute the mean chromosome number for each taxon, and to highlight significant differences among all orders and among subsets of families and genera. For each taxon, we analysed the variability in chromosome number by use of common statistical methods, and computed the frequency of chromosome numbers, the coefficient of variation of chromosome number (CV_CN), the frequency of B-chromosomes (fB), and that of odd chromosome numbers (fOCN). The phylogenetic relevance of our results is discussed and the usefulness of basic karyological data, often neglected in current phylogenetic studies, is stressed.     

A duplication of gcyc predates divergence within tribe Coronanthereae (Gesneriaceae): Phylogenetic analysis and evolution

Recent investigations in Gesneriaceae have indicated that the cycloidea homolog, gcyc, remains functional at the DNA level and rates of sequence divergence in this gene are not statistically different across all taxa regardless of floral symmetry. A duplication of gcyc has been detected within Coronanthereae, a tribe that has phylogenetic affinities to subfamily Gesnerioideae and includes two genera with radially symmetrical corollas. Duplication of gcyc has been detected in all Coronanthereae except Sarmienta. All paralogs appear functional at the DNA level. Likewise, there is no increased sequence divergence between the two copies, nor between species with radially symmetrical flowers to those with bilateral symmetry. The duplication of gcyc in Coronanthereae is most likely a result of polyploidy since Coronanthereae have the highest chromosome counts of all Gesneriaceae.