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1.
总结了虎尾草亚科72属601个分类单位的细胞学资料。虎尾草亚科的染色体基数是10和9,来源于原始染色体基数6经非整倍性减少为5,再经多倍化及非整倍性减少而来。细胞学性状对虎尾草亚科属上类群的分类具有相当重要的价值。推测染色体基数演化的趋势为:x=6→x=5→x=10→x=9。据认为,虎尾草亚科的原始染色体基数为5的二倍体类群在演化早期就灭绝了。 相似文献
2.
沙参属10个种的染色体研究 总被引:3,自引:1,他引:2
本文报道了我国黑龙江产桔梗科沙参属的10种1变种的染色体数目和核型,对其中
7种作了减数分裂行为的观察。 其中6种1变种为首次报道,并发现2n=68的4x种。该
属染色体基数多为17(x=17),但Adenophora trachelioides和A.remotiflora的基数为18
(x=18),为该属独特基数。核型的共同特征是:小型,以中部(m)、近中部(sm)着丝点
染色体为主,至少具一对近端着丝点染色体和一对随体染色体。该属染色体的演化处于二种
水平: 数目变化(包括多倍化和非整倍体变化)和结构变异。 多倍化是该属物种形成的主要
途径之一。结合其它性状讨论了这些种的分类,并确立1个四倍体新种(A. amurica)和1个新组合(A.pereskiifolia ssp.alternifolia)。 相似文献
3.
双花木属和壳菜果属(金缕梅科)的核型研究 总被引:2,自引:1,他引:1
本文对金缕梅科Hamamelidaceae双花木属Disanthus Maxim.的长柄双花木D.cercidifolius subsp.longipes和单种属壳菜果属Mytilaria Lec.首次进行了染色体计数和核型分析。结果表明:长柄双花木与产自日本的双花木D. cercidifolius subsp.cercidifolius的体细胞染色体数目一致,均为2n=16,前者无“st”或“t”染色体,表明该亚种可能比较原始;壳菜果Mytilaria laosensis Lec.的染色体数目为2n=26,x=13。前人报道的金缕梅科染色体基数为x=8和x=12,因此x=13可能是金缕梅科的一个新染色体基数。联系该属的形态特征及其与马蹄荷属Exbucklandia R.W.Brown的关系,作者支持将壳菜果属处理为独立的亚科,即壳菜果亚科Mytilarioideae。 相似文献
4.
银缕梅属(Shaniodendron)染色体数报告 总被引:1,自引:0,他引:1
银缕梅园ShaninodendronM.B.Deng,H.T.WeietX.Q.Wang银缕梅S.subaequale(Chang)Deng,WeietWang发表于1992年,为中国特有的单种属。银缕梅染色体的观察结果表明:银缕梅染色体为小型,点状;2n=24.其染色体数与Anderson&Sax(1935)报道(J,ArnArb.16:210~215)的金缕梅亚科各届染色体大多数为n=12相一致。形状则与Weaver(196)报道(JArnArb50:559~619)的弗特吉属(Fothergilla)的FmajiorLodd相近,但F.majiorn=36该属另一种F.gareniiMurr.n=24,它们的染色体基数均为12,可见银缕梅属与弗特吉属有近缘关… 相似文献
5.
绞股蓝属的染色体研究 总被引:11,自引:2,他引:9
报道了葫芦科绞股蓝属(Gynostemma B1.)8种共20个居群的染色体数目,分别为2n=22,33,44,66,88多倍体现象极为普遍。两个亚属;绞股蓝亚属(Subgen.Gynostemma)和喙果藤亚属(Subgen.Triostellum)的染色体基数均为X=11,并结合该属植物形态特征、繁殖方式和地理分布,对普遍出现的多倍体现象进行了讨论。 相似文献
6.
7.
八种国产大戟属植物的核型报道 总被引:7,自引:0,他引:7
8种大戟属Euphorbia L.植物的核型分析结果表明,大戟属不同亚属的染色体基数与其形态变
异的复杂性有一定关系。地锦草亚属subgen.Chamaesyce 3个种染色体基数分别为x=8,9,11;一品红
亚属subgen.Poinsettia两个种染色体基数均为x=7,分别为四倍体和八倍体;乳浆大戟亚属subgen.
Esula 3个种,染色体基数分别为x=7,10,10。根据以前学者发表的资料分析,一品红亚属和大戟亚属
Subgen. Euphorbia的染色体基数是很稳定的,分别为x=7和x=10;通奶草E.hypericifolia为x=8
的四倍体,它不仅有染色体整倍性的变异,还有异基数性的变化。结合以前学者的研究,笔者支持x=
10为大戟属的最原始基数的观点。齿裂大戟E.dentata和通奶草具不同的染色体倍性,猫眼草E.
esula的细胞染色体数目观察证实了我国存在四倍体的居群,与欧洲和北美的植物构成一个典型的多倍体复合体。 相似文献
8.
葱属Amerallium亚属(石蒜科)的系统发生与性状进化 总被引:1,自引:0,他引:1
运用贝叶斯和简约法对葱属(Allium)Amerallium亚属的核糖体DNA内转录间隔区(ITS)进行了分析,对该亚属的系统发生进行了推测。系统分析证实 Amerallium是单系的,并表明该亚属由三个隔离的地理群组成:北美Ameralliums,地中海区Ameralliums和东亚Ameralliums。性状进化的重建表明鳞茎是原始或祖先状态,根状茎和肉质增粗的根是衍生状态且在Amerallium这个亚属的类群中独立进化发生了几次。重建也表明该亚属的原始染色体基数x=7,其它染色体基数(x=8, 9, 10, 11)是由它转化而来的。在北美类群中,异基数性相当罕见,而多倍性似乎是一个相对频繁的进化事件。在地中海区类群和东亚类群中,异基数性和多倍性是染色体进化的两个主要驱动力。 相似文献
9.
运用贝叶斯和简约法对葱属(Allium)Amerallium亚属的核糖体DNA内转录间隔区(ITS)进行了分析,对该亚属的系统发生进行了推测。系统分析证实 Amerallium是单系的,并表明该亚属由三个隔离的地理群组成:北美Ameralliums,地中海区Ameralliums和东亚Ameralliums。性状进化的重建表明鳞茎是原始或祖先状态,根状茎和肉质增粗的根是衍生状态且在Amerallium这个亚属的类群中独立进化发生了几次。重建也表明该亚属的原始染色体基数x=7,其它染色体基数(x=8, 9, 10, 11)是由它转化而来的。在北美类群中,异基数性相当罕见,而多倍性似乎是一个相对频繁的进化事件。在地中海区类群和东亚类群中,异基数性和多倍性是染色体进化的两个主要驱动力。 相似文献
10.
11.
Basic chromosome numbers of terrestrial orchids 总被引:1,自引:0,他引:1
The chromosome numbers of forty-one Brazilian species belonging to 11 genera of preferentially terrestrial orchids (subfamilies Cypripedioideae, Spiranthoideae, Orchidoideae, and Vanilloideae) were examined. Previous records for these subfamilies were reviewed in order to identify the ancestral chromosome numbers of terrestrial orchids. The variation observed within the subfamilies Spiranthoideae (2n=28, 36, 46, 48 and 92), and Orchidoideae (2n=42, 44, ca. 48, ca. 80, 84, and ca. 168) was similar to that previously reported in the literature. In the subfamily Spiranthoideae, some species of Prescottia (subtribe Prescottiinae) and some genera of Spiranthinae showed a bimodal karyotype with one distinctively large pair of chromosomes. The analysis of chromosome numbers of the genera in subfamilies revealed the predominance of the polyploid series 7, 14, 21, 28, 42 with a dysploid variation of ±1 in each ploidy level. These results suggest that the basic chromosome number of terrestrial orchids is x1=7 for the subfamilies Spiranthoideae and Orchidoideae, as well as other Epidendroid orchids, and that the majority of the genera are composed of palaeopolyploids. 相似文献
12.
A. Randall Olson 《American journal of botany》1993,80(7):839-846
Within the Monotropaceae. Monotropa hypopitys L. has the widest geographical distribution with sporophytes characterized as achlorophyllous, mycotrophic, and morphologically reduced. General and histochemical observations at the light microscope level concerning the postpollination changes in the numerous anatropous, unitegmic ovules reveal a precise embryogeny and endosperm development. Following double fertilization, the primary endosperm cell produces a lipid-rich cellular endosperm situated between a micropylar and a chalazal haustorium. A cytoplasmically unequal division of the elongated zygote initiates proembryo formation. The degeneration of the basal cell of the proembryo results in an isolated terminal cell that undergoes a cytoplasmically equal, transverse division establishing a two-celled embryo embedded in endosperm. Prior to final seed maturation, proteins replace the lipids as the dominant cytoplasmic reserve material. In contrast with earlier studies that depicted the mature embryo as variable in structure, here the embryo is shown to be consistently uniform within and between those populations sampled from North America and Europe. 相似文献
13.
The karyotypes of salmonid fishes including taxa in the three subfamilies Coregoninae, Thymallinae and Salmoninae are described. This review is an update of the (Hartley, 1987) review of the chromosomes of salmonid fishes. As described in the previous review, the karyotypes of salmonid fishes fall into two main categories based on chromosome numbers: the type A karyotypes have diploid numbers close to 80 with approximately 100 chromosome arms (2n = 80, NF = 100), and the type B karyotypes have diploid numbers close to 60 with approximately 100 chromosome arms (2n = 60, NF = 100). In this paper we have proposed additional sub categories based on variation in the number of chromosome arms: the A' type with NF = 110-120, the A" type with NF greater than 140, and the B' type with NF less than 80. Two modes of chromosome evolution are found in the salmonids: in the Coregoninae and the Salmoninae the chromosomes have evolved by centric fusions of the Robertsonian type decreasing chromosome numbers (2n) while retaining chromosome arm numbers (NF) close to that found in the hypothetical tetraploid ancestor so that most extant taxa have either type A or type B karyotypes. In the Thymallinae, the chromosomes have evolved by inversions so that chromosome arm numbers (NF) have increased but chromosome numbers (2n) close to the karyotype of the hypothetical tetraploid ancestor have been retained and all taxa have type A' karyotypes. Most of the taxa with type B karyotypes in the Coregoninae and Salmoninae are members of the genus Oncorhynchus, although at least one example of type B karyotypes is found in all of the other genera. These taxa either have an anadromous life history or are found in specialized lacustrine environments. Selection for increases or decreases in genetic recombination as proposed by Qumsiyeh, 1994 could have been involved in the evolution of chromosome number in salmonid fishes. 相似文献
14.
Jailson Gitaí Juraj Paule Georg Zizka Katharina Schulte Ana Maria Benko‐Iseppon 《Botanical journal of the Linnean Society. Linnean Society of London》2014,176(3):349-368
For the large Neotropical plant family Bromeliaceae, we provide new data on chromosome numbers, cytological features and genome size estimations, and combine them with data available in the literature. Root‐tip chromosome counts for 46 species representing four subfamilies and a literature review of previously published data were carried out. Propidium iodide staining and flow cytometry were used to estimate absolute genome sizes in five subfamilies of Bromeliaceae, sampling 28 species. Most species were diploid with 2n = 50 in Bromelioideae, Puyoideae and Pitcairnioideae, followed by 2n = 48 observed mainly in Tillandsioideae. Individual chromosome sizes varied more than tenfold, with the largest chromosomes observed in Tillandsioideae and the smallest in Bromelioideae. Genome sizes (2C‐values) varied from 0.85 to 2.23 pg, with the largest genomes in Tillandsioideae. Genome evolution in Bromeliaceae relies on two main mechanisms: polyploidy and dysploidy. With the exception of Tillandsioideae, polyploidy is positively correlated with genome size. Dysploidy is suggested as the mechanism responsible for the generation of the derived chromosome numbers, such as 2n = 32/34 or 2n = 48. The occurrence of B chromosomes in the dysploid genus Cryptanthus suggests ongoing speciation processes closely associated with chromosome rearrangements. © 2014 The Linnean Society of London, Botanical Journal of the Linnean Society, 2014, 176 , 349–368. 相似文献
15.
A short review of main cytogenetic features of insects belonging to the sister neuropteran families Myrmeleontidae (antlions) and Ascalaphidae (owlflies) is presented, with a particular focus on their chromosome numbers and sex chromosome systems. Diploid male chromosome numbers are listed for 37 species, 21 genera from 9 subfamilies of the antlions as well as for seven species and five genera of the owlfly subfamily Ascalaphinae. The list includes data on five species whose karyotypes were studied in the present work. It is shown here that antlions and owlflies share a simple sex chromosome system XY/XX; a similar range of chromosome numbers, 2n = 14-26 and 2n = 18-22 respectively; and a peculiar distant pairing of sex chromosomes in male meiosis. Usually the karyotype is particularly stable within a genus but there are some exceptions in both families (in the genera Palpares and Libelloides respectively). The Myrmeleontidae and Ascalaphidae differ in their modal chromosome numbers. Most antlions exhibit 2n = 14 and 16, and Palparinae are the only subfamily characterized by higher numbers, 2n = 22, 24, and 26. The higher numbers, 2n = 20 and 22, are also found in owlflies. Since the Palparinae represent a basal phylogenetic lineage of the Myrmeleontidae, it is hypothesized that higher chromosome numbers are ancestral for antlions and were inherited from the common ancestor of Myrmeleontidae + Ascalaphidae. They were preserved in the Palparinae (Myrmeleontidae), but changed via chromosomal fusions toward lower numbers in other subfamilies. 相似文献
16.
We give the haploid chromosome numbers of 173 species or subspecies of Riodinidae as well as of 17 species or subspecies of neotropical Lycaenidae for comparison. The chromosome numbers of riodinids have thus far been very poorly known. We find that their range of variation extends from n =?9 to n =?110 but numbers above n =?31 are rare. While lepidopterans in general have stable chromosome numbers, or variation is limited at most a subfamily or genus, the entire family Riodinidae shows variation within genera, tribes and subfamilies with no single modal number. In particular, a stepwise pattern with chromosome numbers that are about even multiples is seen in several unrelated genera. We propose that this variation is attributable to the small population sizes, fragmented populations with little migration, and the behavior of these butterflies. Small and isolated riodinid populations would allow for inbreeding to take place. Newly arisen chromosomal variants could become fixed and contribute to reproductive isolation and speciation. In contrast to the riodinids, the neotropical Lycaenidae (Theclinae and Polyommatinae) conform to the modal n =?24 that characterizes the family. 相似文献
17.
The genus Filipendula Mill. is generally separated from Spiraea L. in systematic keys on the basis of a single fruit character. In some taxonomic treatments of the Rosaceae, where subfamilies are used, this places the genera in separate subfamilies. Karyological studies can be useful in assaying the justifiability of such treatment and are needed because of serious discrepancies between previous reports of chromosome numbers and the recent textbook designation, on dubious grounds, of F. vulgaris as an example of a “permanent chromosome hybrid.” The results given in this paper show that x = 7 in this genus (compared with x = 9 in Spiraea) and the reasons for rejecting previous counts of 2n = 15 for F. vulgaris are presented. “Permanent chromosome hybridity” for this species is also rejected. The possibility that a cytotype with 2n = 16 may exist in the northern part of the range of F. ulmaria cannot be completely discounted, but positive evidence is presented for 2n = 14 in this species (even though 2n = 16 has been reported most frequently recently). The basic number 7 for Filipendula is in agreement with the placing of this genus in the subfamily Rosoideae even though the hereditary peculiarities (apomixis and permanent chromosome hybridity) shown by some other members of this subfamily are apparently not now needed to explain the cytological situation in Filipendula. 相似文献
18.
Chromosome numbers are reported for 26 species and varieties of Umbelliferae
which belong to 3 subfamilies and 19 genera in this paper. Of these, 13 counts are
new records and some problems about chromosome numbers of Umbelliferae are simplydiscussed. 相似文献
19.
Chromosome numbers are reported for 26 species and varieties of Umbelliferae
which belong to 3 subfamilies and 19 genera in this paper. Of these, 13 counts are
new records and some problems about chromosome numbers of Umbelliferae are simplydiscussed. 相似文献