贵州大树茶的核型变异与进化

本文对贵州大树茶7种1变种11类型的核型进行了分析。结果表明,这些种类均为二倍体2n＝30。五室茶Camellia quinquelocularis 2n＝30＝24m+6sm;四球茶C．tetracocca 2n＝30=22m+8sm;大理茶C．taliensis 2n=30＝22m+8sm;秃房茶C．gymnogyna 2n＝30＝22m+6sm+2st与2n=30＝20m+8sm+2st;假秃房茶C. gymnogynoides 2n＝30=22m+6sm+2st与2n＝30=20m+8sm+2st;榕江茶C. jungkiangensis 2n＝30+20m+8sm+2st;茶C．sinensis 2n=30＝20m+8sm+2st以及变种淡红花茶C．sinensis var．ruolla 2n＝30=20m+8sm+2st;均属2A核型。染色体结构变异在茶组植物演化中起了重要作用。所划分的两大类核型,即m和sm类与m,sm,和st类是与其子房室数,即5室和3室相一致的。根据核型的不对称性程度、外部形态及生化分析,探讨了各种类的亲缘关系与系统演化途径,论证了茶组植物的原产地是位于滇、桂、黔毗邻交汇处的云贵高原,探讨了茶组植物的分类学问题。     

中国山茶属4种2变种核型研究

本文采用去壁低渗法研究了我国山茶属植物4种2变种的核型。根据Levan等的命名系统,各个种的核型可简式为大理茶2n=20m+2m(SAT)+8sm;勐腊茶2n=20m+2m(SAT)+6sm+2sm(SAT);德宏茶2n=20m+8sm+2sm(SAT);苦茶2n=20m+9sm+1sm(SAT);茶2n=18m+2m(SAT)+12sm;白毛茶2n=18m十2m(SAT)+9sm+1sm(SAT)。这些种都是二倍体种(2n=2x=30),未发现多倍体。在勐腊茶核型中发现2个超数染色体(B-chromosome)。核型的不对称性表明,这些种均属于Stebbins核型分类的2A型核型。这些种在“随体数目和位置,最长染色体与最短染色体之比,臂比大于2:1的染色体比例,着丝点端化值,染色体绝对长度”方面的变异是清楚易见的。核型的变异表明,这些种的染色体进化顺序为大理茶—→勐腊茶—→德宏茶—→普洱茶—→白毛茶—→苦茶—→茶。这一结果与张宏达提出的山茶属植物的分类系统基木吻合。本文还讨论了山茶属植物核型的杂合性和多态性。本文中勐腊茶、德宏茶、苦茶的染色体数目和核型及大理茶的核型为首次报道。     

五种珍珠菜的核型研究

本文对５种珍珠菜亚属植物进行了染色体数目及核型研究。其中瓣珍珠菜２ｎ＝２４＝１２ｍ＋８ｓｍ＋４ｓｔ（２ＳＡＴ）、黑腺珍珠菜２ｎ＝２２＝２ｍ＋４ｓｍ＋６ｓｔ＋１０ｔ、泽珍珠菜２ｎ＝２４＝１４ｍ＋６ｓｍ（２ＳＡＴ）＋４ｓｔ和小叶珍珠菜２ｎ＝４８＝３４ｍ＋１０ｓｍ＋４ｓｔ的染色体数目及核型为首次报道。中国九江产的红根草核型２ｎ＝２４＝２０ｍ＋４ｓｍ（２ＳＡＴ）与日本产的核型２ｎ＝２４＝１８ｍ（１ＳＡＴ）     

广西茶六个品种的核型分析

广西5个农家栽培茶和1个野生茶品种的染色体观察,它们的核型分别为:龙胜单株茶2n=30=18m+2m(SAT)+10 sm;开山茶2n=30=20m+4m(SAT)+6 sm;桂青茶2n=30=20m+2m(SAT)+8 sm;凌云茶2n=30=18m+2m(SAT)+10 sm;排旗茶2n=30=22 m+2m(SAT)+6 sm;扶绥茶(野生品种)2n=30=22 m+8 sm;它们的核型均属“2A”型。并且都为二倍体种。     

长毛红山茶和长尾红山茶的核型分析

<正> 长毛红山茶(Camelliav uillosa Chang et S.Y.Liang)和长尾红山茶(C.longicaudata Chang et S.Y.Liang)均为张宏达教授定的新种,分别隶属于山茶属(Camellia)红山茶组(Sect.Camellia)的滇山茶亚组(Subsect.Reficulala)和光果红山茶亚组(Subsect.Lucidissima),前者分布在我国的湖南、广西和贵州,后者分布在广东和广西。 红山茶组共有33个种、1个亚种,7个变种。根据文献资料统计,该组作过染色体计数的有10个种,1个亚种和6个变种,作过核型分析的有4个种、1个亚种和2个变种。本文对该组的长毛红山茶和长尾红山茶的核型作首次报道,并与该组的10个种,1个亚种和6个变种的染色体数目或核型作了比较。     

五种苏铁属植物的核形态

报道了苏铁属（Cycas L.)5种植物的染色体数目和核型,除多歧苏铁外,其他种均为首次报道。5个种的体细胞中期染色体核型公式分别为：滇南苏铁C.diannanensis K(2n)=2x=22=2m 4sm 4st 12T;潭清苏铁C.tanqingii K(2n)=2x=22=2m 8sm 2st 10T;多歧苏的Cmultipinnata K(2n)=2x=22=4m 8st 2st 8T;巴兰萨苏铁C.balansae K(2n)=2x=xx=2m 4sm 6st 10T。石山苏铁C.miquelii K(2n)=22=2m 6sm(1SAT) 4st 10T;核型均属于3B型。本研究结果支持苏铁属植物的核型从不对称进化的观点;同时,支持将巴兰萨苏铁和石山苏铁归入攀枝花苏铁组的台湾苏铁亚组的观点。     

The discovery of triploid Lycoris sprengeri Comes ex Baker from Anhui,China

Lycoris sprengeri Comes ex Baker is endemic to China. Reported in the present paper are the chromosomes number and karyotypes for two wild populations of the species from Anhui. ( 1 )Caishi population has a karyotype 2n=33=9st+21t+3T. The length of chromosomes ranges from 5.58～9.15μm. The karyotype belongs to Stebbin’s (1971) “4A”. (2)Longyashan populations have two karyotypes. The karyotype formula of the type I is 2n=22=8st+14t, with chromosomes ranging from 6.88～9.15μm. The karyotype belongs to “4A”. The karyotype formula of the type Ⅱ is 2n＝22＝1m+1sm+14st+6t, with chromosomes ranging from 7.20～15.80μm. The karyotype belongs to “3B”. The triploid type of L. sprengeri was discovered in Anhui for the first time. The karyotype 2n=22 =1m+1sm+14st+6t in diploid type of this species is here reported for the first time.The Robertsonian change plays a key role in karyotype evolution of Lycoris.     

黄精属细胞分类学研究——Ⅱ.四川金佛山地区黄精属植物核型

本文对四川金佛山地区4种黄精属植物的核型进行了研究,其结果为:滇黄精:2n=26=6m+12sm(2SAT)+8st(2SAT);距药黄精:2n=26=10m+4sm+12st;垂叶黄精:2n=30=14m(2SAT)+4sm+10st+2t、2n=28=14m+6sm+6st+2t;湖北黄精:2n=30=12m+8sm+10st、2n=28=6m+10sm+10st+2t、2n=22=2m+12sm 8st。通过与其它地区黄精属植物染色体数目与形态的比较,发现本地区所有种类的染色体数目普遍偏高,无论在染色体基数或染色体形态上都比较接近喜马拉雅山地区分布的种类。从实验结果进一步看出了黄精属的染色体变异是相当明显的,并主要表现为非整倍性变异;在有些情况下,染色体数目与结构的变异能与某些形态学特征相联系。     

赖草属5个种的核型与进化

报道了国产赖草属５个种的核型,即大赖草,２ｎ＝４ｘ＝２８＝２４ｍ（２ＳＡＴ）＋４ｓｍ（２ＳＡＴ）;粗穗赖草２ｎ＝４ｘ＝２８＝２２ｍ（２ＳＡＴ）＋４ｓｍ＋２ｓｔ（２ＳＡＴ）;若羌赖草,２ｎ＝４ｘ＝２８＝２０ｍ（４ＳＡＴ）＋６ｓｍ＋２ｓｔ（２ＳＡＴ）;羊草,２ｎ＝４ｘ＝２８＝２２ｍ（４ＳＡＴ）＋２ｓｍ＋４ｓｔ（４ＳＡＴ）;窄颖赖草,２ｎ＝４ｘ＝２８＝２２ｍ（２ＳＡＴ）＋４ｓｍ（２ＳＡＴ）＋２ｓｔ（２Ｓ     

四川产紫堇属四新种

Af finis C. hemsleyanae Franch. et Prain, sed caulibus scapiformibus, flori-lus flavis, majoribus, petalo antico basi saccato facile differt.Herba caespitosa circ. 30 cm longa. Rhizoma circ. 5-10 mm longum, 10 mm crassum, radicibus fibrosis, numerosis, fasciculatis. Caulis 1 usque numerosus, scapiformis, simplex, efoliolatus, interdum basi unifoliatus. Folia basalia numerosa, circ. 20 cm longa, petiolis circ. 15 cm longis basi marginato-expansis, plus minu-sve carnosulis, in sicco purpureo-brunneis, laminis circ. 5 cm longis 5-6 cm latis viridibus, subtus glaucescentibus, biternatis, pinnis brevipetiolulatis, pinnulis sessilibus vel subsessilibus, 2.5-3.5 cm longis, 2 - 3 cm latis bitripartitis, segmentis lanccolatis, saepe trilobatis.     

Studies on the Karyotype of 5 Samples of Allium Sect. Bromatorrhiza Ekberg

The karyotypes of 5 samples in Allium Sect. Bromatorrhiza Ekberg were analysed in this paper. In Allium wallichii Kunth, the first sample is a diploid, with genome formula is AA and karyotype formula is K(2n)=2x=14=2m(SAT)+2m+10sm. The second is an autotetraploid, with genome formula AAAA, karyotype formul K(2n)=4x=28=2m(SAT)+6m+20sm. These two karyotypes belong to “3A”. The two karyotypes of A. wallichii Kunth are similar in morphology, though different in ploidy. In Allium hookeri Thwaites, the first sample is a dibasic autoallotriploid. Its genome formula is AAB₁; the basic number of the genome A is 7 and that of the genome B₁ is 8. The karyotype formula is K(2n)=2x+x'=22=(12sm+2t)+(1m+4sm+1st+2t). The second is also an autoallotriploid. The genomes in pairs are similar to those in the first sample in size and morphology of chromosomes. However, the unpaired genome differs from the first one apparently. Therefore, its genome formula is AAB₂, and karyotype formula is K(2n)=2x+ x'=22=(12sm+2t)+(3m+1sm+2st+2t). The third is doubling of the first karyotype. It is an autoallohexaploid, with genome formula AAAAB₁ B₁ and karyotype formula K(2n)=4x+2x'= 44= (24sm+4t) + (2m+8sm+2st+4t). These three karyotypes belong to “3A”.     

鹅观草属五个类群的核型与进化

报道了鹅观草属５个类群的核型,即长芒鹅观草,核型２ｎ＝４ｘ＝２８＝２２ｍ＋６ｓｍ（２ＳＡＴ）;短颖鹅观草,核型２ｎ＝４ｘ＝２８＝２０ｍ（２ＳＡＴ）＋８ｓｍ（２ＳＡＴ）;短柄鹅观草,核型２ｎ＝４ｘ＝２８＝２２ｍ（２ＳＡＴ）＋６ｓｍ;纤毛鹅观草,核型２ｎ＝４ｘ＝２８＝２０ｍ＋８ｓｍ（４ＳＡＴ）;毛盘鹅观草,核型２ｎ＝４ｘ＝２８＝１８ｍ＋６ｓｍ（４ＳＡＴ）＋４ｓｔ。同时,通过核型重要性状的递变分析,揭示了鹅观草属５个类群的相对进化程度以及宏观分类中４个组的系统发育关系,表明鹅观草属的半颖组在系统发育中可能既派生了颖体短小的小颖组,又派生了颖体长大的大颖组和长颖组。     

横断山区伞形科4种7个居群植物的核型研究

对横断山区伞形科棱子芹属2种植物(松潘棱子芹Pleurospermum franchetianumHemsl.和西藏棱子芹Pleurospermum hookeriC.B.Clarke var.thomsoniiC.B.Clarke)和茴芹属2种植物(异叶茴芹Pimpinella diversi-foliaDC.和锐叶茴芹Pimpinella argutaDiels)共7个居群进行体细胞染色体数目观察和核型比较分析,结果表明,棱子芹属和茴芹属植物属内种间染色体基数存在差异,其中松潘棱子芹为2n=2x=18=16sm 2st,西藏棱子芹为2n=2x=22=16m 6sm;茴芹属光果组中锐叶茴芹为2n=2x=22=22m,毛果组中异叶茴芹为2n=18=18st或2n=18=2sm 16st.松潘棱子芹、西藏棱子芹、锐叶茴芹的染色体数目和核型均为首次报道,从而为棱子芹属和茴芹属的分类和演化研究提供细胞学依据.     

安徽黄精属的细胞分类学研究

本文首次报道黄精属ＰｏｌｙｇｏｎａｔｕｍＭｉｌｌ我国三种特有植物的染色体数目和核型,结果如下：安徽黄精Ｐ．ａｎｈｕｉｅｎｓｅ发现两个细胞型：（１）２ｎ＝２４＝４ｍ＋６ｓｍ＋１４ｓｔ;（２）２ｎ＝２０＝４ｍ十６ｓｍ＋１０ｓｔ;　　黄精Ｐ．ｌａｎｇｙａｅｎｓｙ２ｎ＝１８＝６ｍ＋８ｓｍ＋４ｔ;距药黄精Ｐ．ｆｒａｎｃｈｅｔｉｉ有三个细胞型：（１）２ｎ＝２２＝８ｍ＋８ｓｍ（２ｓｃ）＋６ｓｔ;（２）２ｎ＝２０＝２ｍ＋１４ｓｍ＋４ｓｔ;（３）２ｎ＝１８＝４ｍ＋８ｓｍ＋４ｓｔ＋２Ｔ,全部属３Ｂ核型。黄精属植物安徽共有１０种,本文对９种黄精的染色体数目、核型进行了比较研究,发现它们可划分成三个类群,与中国植物志（第十五卷）的形态分类基本相符。     

Cytotaxonomical Studies on Liliaceae (s.l.): (2) Report on Chromosome Numbers and Karyotypes of 8 Species of 8 Genera from Zhejiang,China

Eight species in eight genera of Liliaceae from Zhejiang were cytotaxonomically studied in this work. The karyotypes of Chinese materials of these species are mostly reported for the first time. The results are shown as follows (see Table 2-4 for chromosome parameters of them): 1. Disporum sessile D. Don Sixteen chromosomes are counted at metaphase of roottip cells.The Karyotype formula is 2n=16=2lm+2sm+4st+2sm+3sm+ 1sm(SAT)+2st (Plate 1: 2-3, see Fig. 1:1 for its idiogram). The Karyotype belongs to 3B in Stebbins’ (1971) karyotype classification, and consists of four pairs of larger chromosomes (1-4) and four pairs of smaller chromosomes (5-8). One SAT-chromosome is situated at the sixth pair. The chromosomes range between 4.85-16.63μm. The karyotypic constitution is similar to that of Japanese material reported by Noguchi (1974). Chang and Hsu (1974) reported 2n=14=13st+1sm and 2n= 16=2m + 13st + 1sm for the material from Taiwan under the name of D. shimadai Hay. (=D. sessile D. Don). Compared with our result of D. sessile, the differences are obvious. 2. Polygonatum odoratum (Mill.) Druce PMCs diakinesis shows eleven bivalents, n = 11, 5 large and 6 small (Plate 2:5). The meiosis is normal. The majority of reports of this species are 2n=20, with a few 2n=22 and 30 (see Table 1). The materials from southen Siberia and the Far East in USSR are all of 2n= 20. Our result is the same as recorded by Jinno (1966) in the Japanese material and by Li (1980) from Beijing. Ge (1987) reported 2n=20 in the cultivated individuals of Shandong, China, showing that both 2n=20 and 22 exist in China. 3. Scilla scilloides (Lindl.) Druce This species has the somatic chromosome number 2n=18 (Plate 1: 4-6, see Fig. 1:2 for its idiogram), of which two groups of chromosomes can be recognized, i.e. the 1 st -5 th pairs of large and the 6 th-9th pairs of small chromosomes. A distinct character of the karyotype is that two satellites are attached to the short arms of the 1st pair of chromosomes. The degree of asymmetry is of 3C. The karyotype formula is 2n = 18 = 2sm (SAT) + 6st + 2t+ 6m + 2sm. The chromosomes range from 2.02 to 11.93 μm. The Previous counts on the species are 2n = 16, 18, 26, 34, 35, 36 and 43 (see Table 1). The present investigation confirms Noda’s and Haga’s results. The species is considered to be of two genomes, namely A(x = 8) and B(x = 9). Our result shows a genome composition of BB, having a pair of large SAT-chromosomes. Chang and Hsu (1974) reported 2n = 34 from a population of Taiwan, an amphidiploid (AABB), Karyotypes of other Chinese populations are worth further researches. 4. Tricyrtis macropoda Miq. The chromosome number of somatic cells is 2n= 26, and PMCs MII shows 13 bivalents (n= 13) (Plate 3:1-3, see Fig. 1:3 for its idiogram). The karyotype formula is 2n= 26= 6m + 10sm + 6st + 4st (or t), which is composed of chromosomes: 4L + 22S in size. The degree of asymmetry is of 3B. No centromeres of the 12th and 13th pairs of chromosomes were observed at metaphase, and the chromosomes may be of st or t. Nakamura (1968) reported 2n= 26(4L+ 22S)= 2sm+ 2sm-st+ 14st-sm+ 8st for T. macropoda Miq. and 2n= 26(4L+ 22S)= 8m+ 2sm+2sm-st+ 2st-sm+ 12st for its ssp. affinis, both from Japan. It is clear that the major character of their karyotypes, i. e. 4L + 22S, is consistent with that reported here. Based on the previous and present reports, all Tricyrtis species studied are remarkably uniform in the basic karyotype, i. e. 4L + 22S. 5. Allium macrostemon Bunge. The present observation on the root-tip cells of the species shows 2n = 32 (Plate 3: 4-5, see Fig. 1:4 for its idiogram). The karyotype formula is 2n (4x)= 32= 26m + 6sm, which belongs to 2B, being of high symmetry. Except the 6th, 10th and 13th pairs of chromosomes all the are metacentric. Chromosomes of this species are large, ranging from 5.94 to 18.06 μm. Our result agrees with Kawano’s (1975) report under the name of A. grayi Regel ( = A. macrostemon, Wang and Tang 1980). 6. Asparagus cochinchinensis (Lour.) Merr. Ten bivalents were observed in PMCs MI, n=10 (Plate 1: 1). The present result confirms the number of a population of Taiwan recorded by Hsu (1971). 7. Ophiopogon japonicus (L. f.) Ker-Gawl. The species from Mt. Taogui, Hangzhou, is found to have 2n (2x)=36=22m + 14sm (Plate 2: 1,5, see Fig. 1:5 for its idiogram) which belongs to 2B. The karyotype is composed of 2 medium-sized chromosomes with metacentric centromeres and 34 small chromosomes, ranging from 1.34 to 4.92 μm. The populations from Mt. Tianzhu and Mt. Yuling, Zhejiang, are found to be aneuploids at tetraploid level (2n=64-70). It is interesting that Nagamatsu (1971) found the karyotypes of Japanese materials to be 2n= 67 and 68, also showing unsteady 4x karyotypes of this species. In the previous. reports (see Table 1), the chromosome numbers of this species are mainly 2n = 72, besides 2n = 36 recorded by Sato (1942) from Japan. 8. Liriope platyphylla Wang et Tang The somatic complement of the species collected from Mt. Tianzhu, Hangzhou, is 2n = 36 (Plate 2: 3-4, see Fig. 1:6 for its idiogram). The karyotype is 2n(2x) = 36 = 16m + 20sm, belonging to 2B type. The chromosomes are small except the medium-sized, 1st pair and the range is from 1.27 to 5.19μm. The material from Mt. Yuling, Zhejiang, is found to have a variety of chromosome numbers (2n= 60-71), as observed in Ophiopogon japonicus. Hasegawa (1968) reported the karyotype of 2n = 72 (4x) from Japan The 2x karyotype is first recorded. This genus is closely related to Ophiopogon. Based on the Hasegawa’s and present studies, all the species in these two genera are remarkably uniform in karyo-type. Therefore, the taxonomy of the two genera is worth further researches.     

黄精属的细胞分类学研究Ⅰ.8个种的核型和进化

作者研究了中国产黄精属8个种的核型,结果如下:热河黄精,2n=22=14m(4SAT)+2sm(SAT)+6st;多花黄精,2n=22=8m+8sm(2sc)+6st(2sc);玉竹,2n=20=12m+8sm;小玉竹,2n=20=8m(2sc)+8sm+4st;长梗黄精,2n=16(18)=10m+4sm+2st;二苞黄精,2n=18=8m+10sm;黄精,2n=24=4m+8sm(2sc)+12st(2sc);卷叶黄精,2n=20=12m(2sc)+8sm。作者推测该属的染色体基数x=10。染色体数目进化的趋势是:非整倍性变异为主,整倍性变异为次;上升性变异为主,下降性变异为次。按照核型不对称程度,8个种的核型可分为三个等级。核型由对称向不对称进化是与染色体数目的进化趋势大体上相关的。     

黄精属细胞分类学研究——Ⅲ.国产6种黄精的染色体数目和核型

本文对国产6种黄精的染色体数目和核型进行了研究,结果为:康定玉竹2n=28=6m+8sm+14st;狭叶黄精2n=30=12m+12sm+6st;毛筒玉竹2n=22=6m+6sm+10st;大苞黄精2n=22=4m+12sm+6st;轮叶黄精有两种细胞型,分别为2n=54和2n=58;点花黄精2n=90;此外,在部分类群中还发现有明显的杂合现象。作者通过与现有资料进行对比,对各类群染色体数目和结构变异的特点和机制进行了初步分析。     

Studies on Karyotypes of 5 Species in Ranunculus from Jiangxi

The present paper reports the chromosome numbers and karyotypes of 5 species in Ranunculus from Jiangxi. The result is shown in Table 1-2. The chromosome numbers of R. ternatus Thunb. (2n=4x=32; 2n=2x=16=8m+2sm+6st) , R. polii Franch. (2n = 2x = 16 = 8m+2sm+6st) and R. sieboldii Miq. (2n = 8x-1 = 63 = 15m+18sm+22st+8t) are first reported. The essential points are as follows: (1) The karyotypes of R. ternatus Thunb. and R. polii Franch. are rather similar, which shows a close relationship between the two species. (2) Polyploid complexes are common in Ranunculus. (3) According to the taxonomical system of Wang Wen-cai, the karyotypes of the two species investigated in Sect. Auricomus belong to “2A” of Stebbins; that of the only species in Sect. Hecatonia belong to “2B'; the karyotypes of the two species investigated in Sect. Ranunculus belong to “3A” or “3B”. The relationships among the three sections from thekaryotype are basically consistent with those based on morphology.     

毛茛属五种植物的核型

对中国云南毛茛属（Ranunculus）5种植物核型进行研究,结果表明,毛茛组茴茴蒜（Ranunculus chinensis Bunge）和禺毛茛（R．cantoniensis DC．）核型公式为2n=2x=16=6m＋4sm＋6st和2n=4x=32：14m＋6sm＋12st;该组茴茴蒜、禺毛茛和扬子毛茛（R．sieboldii Miq．）的不同居群核型存在自西向东不对称系数渐增大现象。在美丽毛茛组中,深齿毛茛（R．pulchellusvar．stracheyanus Hand．-Mazz．）的中甸居群核型（2n=4x=32=12m＋12sin＋8st）与青海居群核型（2n：4x：32：24m＋8sm）明显不同;毛果高原毛茛（R．tangusticusvar．dasycarpus（Maxim．）L．Liou）染色体数目（2n=40）,核型公式（2n=5x=40=30m＋10sm）和纳帕海毛茛（R．napahaiensis W．T．Wang＆L．Liao）染色体数目（2n=40）,核型公式（2n=5x=40=20m＋16sin＋4st）为首次报道。     

Karyotype Comparison of Populus SectTacamahaca

The paper identified and compared the karyotypes of 10 species(varieties) of Populus sectTacamhaca.The results were as follows:Ppseudo simonii Kitag.2n=38=27m+6sm(1SAT)+4st(2SAT)+1t(1SAT);Ptrichocarpa Torr.2n=38=2M+18m(1SAT)+8sm+10st(1SAT);Pcathayana Rehd.var.Beijing 2n=38=1M+24m+6sm+7st(2SAT);Pבpopularis’ 2n=38=3M+27m+2sm(1SAT)+4st(2SAT)+2t(1SAT);Pcathayana Rehd.var.Wutai 2n=38=5M+22m+4sm+5st+2t(2SAT);Pcathayana Rehd.var.Gansulinxiaman 2n=38=2M+28m+1sm+7st(1SAT);Pcathayana Rehd.var.Qinghai 2n=38=1M+27m+3sm+6st(3SAT)+1t(1SAT);Pcathayana×Zhongqing 10 2n=38=1M+26m+4sm+5st(2SAT)+2t(2SAT);Pcathayana×Zhongqing 48 2n=38=16m+10sm(1SAT)+10st(2SAT)+2t(1SAT).The results showed definite karyotype differences among the species of Tacamhaca.The karyotypes of most species(varieties) are made of m and sm and a few with st and t chromosomes.The karyotypes of Tacamhaca were all of 2B type of Stebbins.This study provided important basic data for taxon of Populus.