银兰和金兰的核型研究

本文报道了国产头蕊兰属植物银兰和金兰的核型： (1)银兰为 2n=34=10m十14sm＋10st。金兰有两种细胞型,A型为2n＝34＝8m+16sm十10st;B型为2n=34=8m+22sm十4st。 后者为一个由染色体结构变异所产生的易位同型纯合子 (translocation homozygote),是由A型通过第1对染色体的短臂与第3对染色体的长臂之间的易位所产生。 在植株外部形态上未见明显差异。 (2)按Stebbins(1971)的标准,三种核型均属不对称的“3C”型。     

葱属粗根组5种材料的核型研究

本文分析了葱属Allium粗根组Sect．Bromatorrhiza Ekberg五群材料的核型。多星韭Allium wallichii Kunth有两个类型：第一类型是二倍体,染色体组公式为AA,核型公式为K(2n)=2X=14=2m(SAT)+2m+10sm,属2A型;第二类型是同源四倍体,染色体组公式为AAAA, 核型公式为K(2n)＝4X＝28＝2m(SAT)+6m十20sm,属2A型。宽叶韭Allium hookeri Thwaites有三个类型： 第一类型是双基数同源异源三倍体,染色体组公式为AAB1,核型公式为 K(2n)＝2X+ x'＝22＝(12sm+2t)十(1m十45m+1st+2t), 属3A型; 第二类型也是双基数同源异源三倍体,能配对的两个染色体组染色体大小和形态与第一类型大体相似,不能配对的一个染色体组染色体大小和形态与第一类型有明显区别,其中至少有两条染色体发生了罗伯逊易位,出现一条很大的染色体和一条很小的染色体,染色体组公式为AAB2,核型公式为K(2n)=2x+x'＝22=(12sm+2t)+ (3m+1sm十2st+2t),属3A型;第三类型相当于第一类型染色体的自然加倍,是双基数同源异源六倍体,染色体组公式为AAAAB1B1,核型公式为K(2n)=4X十2x'＝44＝(24sm+4t)十(2m+ 8sm十2st+4t),属3A型。     

滇蜀豹子花核型及其变异研究

本文详细报道了滇蜀豹子花的核型,发现居群中存在两种细胞型,即A型和B型。A型参考核型为2n = 24＝2m(2SAT)+2sm+8st(4SAT)+12t(2SAT),其第3号两条同源染色体长臂均无居间随体：B型参考核型为2n=24＝2m(2SAT)+2sm+8st(2SAT)+12t(3SAT)+0—1b,其第3号一条同源染色体长臂紧靠着丝点处有一大而明显的居间随体,而另一条同源染色体则无,构成明显的3号染色体的结构杂合性。统计表明,居群中二者的比例近似为1A;2B。研究还发现了大量的体细胞染色体结构变异核型,表明滇蜀豹子花核型尚未趋于稳定,还处于强烈分化之中,高频率的体细胞染色体结构变异是其种内分化不可忽视的一种进化要素。     

风毛菊属5种植物的核型分析

采用常规压片法,对风毛菊属(Saussurea)5种植物的染色体数目和核型类型进行分析。结果表明:大耳叶风毛菊(S.macrota)核型公式为2n=2x=26=10m+12sm+4st,属2A型;长梗风毛菊(S.dolichopoda)核型公式为2n=2x=26=14m+8sm+4st,属2A型;川陕风毛菊(S.licentiana)核型公式为2n=2x=28=12m+16sm,属2B型;杨叶风毛菊(S.populifolia)核型公式为2n=2x=28=6m+18sm+4st,属2B型;尾叶风毛菊(S.caudata)核型公式为2n=2x=30=14m+14sm+2st,属2A型。这5种风毛菊属植物中,除大耳叶风毛菊染色体数目和核型类型与前人报道的一致外,其余4种植物的染色体数目和核型类型均为首次报道,并在川陕风毛菊中发现1对B染色体。     

百合科六属十五种植物的细胞学研究

本文对云南西北部百合科6属15种的染色体和核型进行了报道。 (1)Clintonia udensis Trautv．et Mey间期核属于浓密分散型,前期染色体属于渐变型,分裂中期体细胞染色体2n=14=8m+4sm+2st(2SAT),核型不对称性属于2A型;(2)鹿药属四个种间期核属于复杂中央微粒型,前期染色体属于中间型,分裂中期体细胞染色体分别为Smilacina henryi(Baker)Wang et Tang,2n=36=12m+16sm+6st+2t(2SAT), 核型不对称性属于2C型;Smilacina fusca Wall., 2n=36=14m(2SAT)+12sm+10st(2SAT), 核型不对称性属于2B型; Smilacina tatsienensis(Franch．)Wang et Tang, 2n=36=22m+2sm+2st(2SAT), 核型不对称性属于2C型;Smilacina atropurpurea(Franch．)Wang et Tang,2n=36=18m+6sm(2SAT)+12st,核型不对称性属于2C型;(3)黄精属四个种的间期核属于复杂中央微粒型,前期染色体属于中间型,分裂中期体细胞染色体分别为Polygonatum kingianum Coll．et Hesml．,2n=30=12m(2SAT) +6sm+lst+2t, 核型不对称性属于2C型; Polygonatum cirrhifolium(Wall．) Royal,2n=30=10m+4sm+12st+4t, 3C型; Polygonatum curvistylum Hua, 2n=78=24m(2SAT)+14sm(6SAT)+40st, 核型不对称性属于3C 型; Polygonatum cathcartii Baker,2n=32=12m+6sm+10st+2t+2bs,核型不对称性属于2C型;(4)百合属,假百合属,豹子花属三个属的间期核和前期染色体形态相似,都属于复杂中央微粒型,前期染色体属于中间型,分裂中期体 细胞染色体分别为Lilium henricii Franch,2n=24=2m(2SAT)+2sm+10st+10t,核型不对称性属于3A型;Lilium bakerianum Coll．et Hesml．var． rubrum Stearn, 2n=24=4m (2SAT)+10st+10t(2SAT),核型不对称性属于3A型;Nomocharis bilouensis Liang 2n=24=2m(2SAT)+2sm+12st+8t,核型不对称性属于3A型;Nomocharis pardanthina Franch．,2n=24=4m(2SAT)+12st (2SAT)+8t,核型不对称性属于3A型;Nomocharis sauluensis Balf, f.,2n=24=4m(2SAT)+10st(2SAT)+10t,核型不对称性属于3B型;Notholirion campanulatum Cotton et Stearn2n=24=2m(2SAT)+2sm+14st(2SAT)+6t,核型不对称性属于3A型。     

新疆猪毛菜属4种植物核型分析及进化研究

采用常规压片法,对钠猪毛菜、准噶尔猪毛菜、小药猪毛菜和薄翅猪毛菜等4种新疆猪毛菜属植物的染色体核型进行了分析,并对已报道的12种新疆猪毛菜属植物核型进行了比较.结果表明:(1)钠猪毛菜体细胞染色体数2n=2x=18=12m+6sm,准噶尔猪毛菜、小药猪毛菜体细胞染色体数为2n=2x=18=18m,该3种均属于1A型;薄翅猪毛菜体细胞染色体数为2n=2x=54=50m+2sm+2st,属2A型;(2)12种新疆猪毛菜属植物核型比较结果证明,猪毛菜属植物的染色体基数为9,钠猪毛菜、准噶尔猪毛菜和小药猪毛菜均为二倍体,薄翅猪毛菜为六倍体,钠猪毛菜和准噶尔猪毛菜具有随体.准噶尔猪毛菜、小药猪毛菜、薄翅猪毛菜属植物的核型均属于首次报道.     

多花水仙(Narcissus tozetta L.)染色体基数x=10和X=11之间进化关系的研究

多花水仙的染色体基数有x=10和x=11两类。基数x=10组型有两种,一种是具6长、4短的典型不对称的二形染色体组型;另一种是具有4长、2中、4短(或5长、2中、3短)的非二形染色体组型。基数x=11则具有4长、2中、5短(或5长、2中、4短)的非二型或非典型二形的染色体组型。x=10的典型不对称的二形染色体组型是原始的组型。基数x=11是从原始的x=10、2n=20组型中的(第5、6号)染色体发生不等长易位后,增加了一对短小的中着丝粒染色体而形成的。另一个x=10、2n=20的非二型新组型,可能从x=11组型丢失了短小的中着丝粒染色体衍生而来,也可能从易位后的个体所产生的不含中着丝粒染色体的雌、雄n配子结合而得到。     

海芋细胞遗传学及花粉发育的研究

采用常规压片法和去壁低渗Giemsa法,研究了海芋Alocasia odora(Lindl.)K.Koch同一居群5株不同个体的细胞遗传学行为和花粉发育过程.结果表明:(1)海芋的体细胞染色体核型为2n=28=20 m 8 sm,染色体长度变化在7.84～12.08 μm,核型不对称类型为2A ;(2)5个不同植株减数分裂中期I构型在同一个体中是相对稳定的,在不同个体间存在差异,各株平均构型分别为① 5.61Ⅱ0 3.72Ⅱ 0.89Ⅳ0 0.06Ⅴ 0.78Ⅵ0 0.06Ⅻ;② 10.38Ⅱ0 3.63Ⅱ;③ 9.15Ⅱ0 2.85Ⅱ 1Ⅳ0;④ 7.76Ⅱ0 3.76Ⅱ 1.24Ⅳ0 ;⑤ 8.52Ⅱ0 3.41Ⅱ 1.03Ⅳ0.有4个株型具有多价体配对,可形成4条、5条、6条、以及12条染色体连成的环状或链状结构,推测存在染色体相互易位等异常现象,为易位杂合体.(3)减数分裂过程中后期Ⅰ存在染色单体桥和落后染色体,占观察细胞的15.5%;(4)成熟花粉球形,有刺状纹饰,为二细胞型花粉,醋酸洋红压片统计成熟花粉的育性,其败育率为9.3%.     

普通小麦栽培品种丰抗13的4B—1D染色体易位的鉴定

通过细胞学观察,在普通小麦栽培品种“丰抗13”和“京红1号”的杂交后代中,发现有多价体出现,这就表明有染色体易位发生。为进一步弄清究竟是哪条染色体发生了易位,我们采用单体测交方法,观察鉴定所有各单体系F_1的花粉母细胞第一次减数分裂中期Ⅰ(以下简称PMCs中Ⅰ)染色体构型。从鉴定结果发现,凡2n=42的F_1 PMCs中Ⅰ出现19~Ⅱ 1~Ⅳ,而2n=41的F_1PMCs中Ⅰ的染色体构型不同,单体与易位有关的两个单体系4B和1D F_1 PMCs中的Ⅰ构型中有部分呈现为19个二价体加1个三价体,即19~Ⅱ 1~Ⅲ,没有单价体,而其余各单体系F_1 PMCs中Ⅰ构型则表现为18个二价体,1个四价体和1个单价体,即18~Ⅱ 1~Ⅰ 1~Ⅳ。因此,可以肯定“丰抗13”存在1个染色体易位,其有关染色体就是4B和1D。     

贵州产蜘蛛抱蛋属植物的细胞分类学研究

报道了6种贵州产蜘蛛抱蛋属植物的染色体数目和核型,并与其相应近缘种对比,联系植物的外部形态特征,探讨核型结构与形态特征的相关性.发现1个种的染色体数目为2n =36,5个种的染色体数目为2n =38,核型公式分别为:平塘蜘蛛抱蛋(Aspidistra pingtangensis),2n =38 =20m +4sm(2sat) +14st;荔波蜘蛛抱蛋(A.liboensis),2n =38 =22m(2sat)+4sm+ 12st;赤水蜘蛛抱蛋(A.chishuiensis),2n =38 =22m(2sat)+8sm +8st;伞柱蜘蛛抱蛋(A.fungilliformis),2n =36=18m (2sat) +4sm+ 14st;四川蜘蛛抱蛋(A.sichuanensis),2n =38 =22m (2sat) +4sm +12st;丛生蜘蛛抱蛋(A caespitosa),2n =38 =20m +6sm(2sat) +12st.核型类型都为2C型.其中平塘蜘蛛抱蛋、荔波蜘蛛抱蛋和赤水蜘蛛抱蛋的染色体数目和核型均为首次报道.研究结果表明,该属植物的核型结构与外部形态特征具有一定的相关性,细胞分类学研究可以为该属植物起源进化研究以及自然分类鉴定提供一定的依据.     

KARYOTYPE POLYMORPHISM IN DIFFERENT GEOGRAPHIC POPULATIONS OF GREEN PEACH APHID MYZUS PERSICAE (SULZER) IN CHINA*

Abstract This paper deals with the karyotype of green peach aphid, Myzus persicae (Sulzer), with three different life cycles in different regions of China. The results showed that four types of karyotype were found in the natural populations of red form and brown form aphids. Four types of karyotype are as follows: 2n = 12 with autosomes 1, 3 translocated (T_1–3); 3n = 18 normal triploid; 3n = 18 with T_1–3 translocation; and 2n = 11. However, in the yellowish‐green aphids there were only two types of karyotype, normal karyotype 2n= 12 (NK) and 2n = 12 with T_1–3 translocation. There was no significant difference in the relative lengths of chromosomes in 2n = 12 karyotype among different color forms and groups from different regions.     

核桃属部分种的小孢子发生及核型研究

本试验采用常规压片法,观察了核桃属(Juglans L.)四个种花粉母细胞(PMC)的减数分裂过程和花粉形态,检测了两个种的花粉生活力,分析研究了七个种的核型。结果表明,普通核桃(J.regia)核桃楸(J.mandskurica Maxim.)和黑核桃(J.nigra L.)的PMC减数分裂基本正常,但河北核桃PMC的减数分裂过程都极不正常,供试的七个种,除普通核桃为2C核型外,其余均为2B核型,仅黑核桃一种带有随体染色体。根据核型特点把七个种分成三组,并探讨了组间与组内种间的亲缘演化关系。作者认为,河北核桃应为一种独立的种,核桃科在系统发育上可能来源于染色体基数为8的两群)不同植物。     

二倍体石蒜在安徽发现

本文以根尖细胞为材料,观察了石蒜Lycoris radiata(L′Her．)Herb．三个不同居群植物的染色体数目和核型,发现石蒜为一复合体,包括两种不同类型：(1)三倍体类型,主要包括一群以鳞茎无性繁殖的园艺栽培植株,其染色体数目和核型为2n＝33=33t(st),属“4A”核型,且极其稳定。(2)二倍体类型,主要包括一群野生植株,变异较大,我们发现有下列几种情况：一是芜湖产石蒜(L．radiata)的野生材料,其染色体数目和核型为2n=21+1B=1m+12st+8t+1B,属“3A”核型,在石蒜种内迄今未见有类似报道;另一是黄山产野生材料,观察到两个细胞型,绝大多数细胞为2n=22＝12st+1Ot,极个别细胞出现2n＝22+1B=6st+14t+2T+1B的情况,均属“4A”核型。芜湖和黄山野生材料的染色体数目和核型均为首次报道。石蒜(L．radiata)的二倍体类群也是首次在安徽发现。     

A Study on Karyotypes of the Genus Lycoris

The genus Lycoris (Amaryllidaceae) consists of about 20 species, all of which are confined to temperate China, Japan and Korea. Cytological investigations, including a reexamination of the karyotypes of 14 taxa, measurements of relative nuclear DNA content, and meiotic configuration observations on some specific forms and interspecific hybrids, have been carried out by the present authors in order to re-evaluate the mode of karyotype evolution and the role of hybridization in the speciation of Lycoris. These have resulted in a new theory for explaining the karyotype evolution in the genus, which will be considered elsewhere. The present paper deals with observations on karyotypes of 11 species, 1 variety and 2 artificial hybrids. Results obtained through karyotype analysis, as shown by the data in Table 1, Plates I-VI and Figs. 1-2, reveal that: (1) the karyotypes of Lycoris rosea, L. radiata var. pumila, L. sprengeri, L. haywardii, L. caldwellii, L. squamigera and L. radiata are, on the whole, consistent with those reported by the previous authors^{[1,2,3,4,5,8,10,12]};(2) the I (rodshaped) chromosomes of L. chinensis and L. longituba are all T’s (telocentric) instead of t’s (acrocentric) or t(Sat)’s; (3) the three materials of L. aurea of different sources have shown a karyotypic differentiation: one with 2n=14=8m+6T, and the others with 2n=16=6m+10T: (4) both of the karyotypes of L. straminea and L. albiflora are 2n=19=3V+6I, inconsistent with 2n=16=6V+10I for the former and with 2n=17=5V+12I for the latter as reported by Inariyama (1953), Bose and Flory (1963) and Kurita (1987). The following aspects are worthwhile discussing: 1. The types of chromosomes. Karyotype analyses reveal the existence of three major chromosome types in Lycoris: (1) m (metacentric) chromosomes: (2) t (acrocentric) chromosomes, with short arms, (3) T (telocentric) chromosomes, sometimes with dot-like terminal centromeres. To distinghish t’s from T’s is of paramount importance for solving the problem of karyotype evolution in Lycoris. Bose (1963) pointed out that in the species with 2n=22, all I chromosomes were t’s, while in species with 2n=12-16, all I chromosomes were T’s. Our results of chromosome observations are consistent with Bose’s remarks. Some authorst^[3,6] have probably mistaken the dot-like terminal centromeres of T’s of L. longituba and L. chinensis as the short arms of t’s. 2. The significance of Robertsonian change in karyotype evolution. Although chromosome numbers and karyotypes are very variable in Lycoris, as shown in Table 1, the total number of arms of a chromosome complement of any species is always multiples of 11. Hence, it seems likely that Robertsonian changes have taken part in karyotype alteration, The genus has a series of basic chromosome numbers: 6, 7, 8 and 11. But which is the most primitive one? It is uncertain whether a successive decrease in chromosome numbers as a result of Robertsonian fusion or a gradual increase in chromosome numbers brought about by fission (fragmentation) has been the essential mechanism for karyotype evolution and speciation in Lycoris. These problems are of crucial importance and will be discussed in our subsequent papers. 3. The origin of polyploids. As evident from Table 1, there are two levels of ploidy differentiation in Lycoris: (1) di ploids with 2n=22 or the equivalent of 22, (2) triploids with 2n=33 or the equivalent of 33. The most common way of origination of triploids in plants is the hybridization of diploids with Tetraploids. But tetraploids have never been found in Lycoris. Thus, it is suggested that the triploids have originated from the combination of an unreduced gamete of a diploid with a normal gamete of another diploid. 4. The role of hybridization in speciation. Results of karyotype analyses show that hybridization has taken an important part in the speciation of Lycoris. Two types of hybrids have been found: (1) 2n=19= 3V+ 16I, L. straminea, L. albiflora and the two artificial hybrids L. sprengeri×L. chinensis and L. haywardii× L. chinensis all possess this karyotype. It could be seen from the above chromosome number and karyotype that this sort of karyotype is exactly half of the total sum of 2n=22I and 2n=16= 6V+10I. It is, therefore, quite evident that taxa possessing this karyotype are all diploid hybrids of 2n=22 and 2n=16, (2) 2n=27=6V+21I, L. caldwellii and L. squamigera possess this karyotype. It is reasonable to assume, too, that they are segmental allotriploids and have arisen from the combination of an unreduced diploid gamete of 2n=16 and a normal haploid gamete of 2n=22. The origin of the hybrid karyotype 2n=17=5V+12I reported by Inari- yama (1953) is similar to that of 2n=19, except that one of the parents possesses 2n=12= 10V+2I instead of 2n=16=6V+10I. The origin of the other hybrid karyotype 2n=30=3V+ 27I reported by Bose (1963) is similar to that of 2n=27, but the diploid gamete comes from taxa possessing 2n=22 instead of 2n=16.     

The inheritance of natural chromosomal polymorphisms in the aphid Myzus persicae (Sulzer)

Two types of chromosomal abnormality have been found in natural populations of Myzus persicae in Japan. One type is apparently due to an autosome 3 dissociation, giving a 2n=13 karyotype. The other is interpreted as a translocation between autosomes 1 and 3, resulting in a 2n=12 complement with marked structural heterozygosity. In laboratory crosses, both types of abnormality were inherited through the sexual phase. The proportions of each type in the F₁ agreed well with expectations, except that no forms homozygous for the translocation were obtained from crosses between translocation heterozygotes, and no karyotypes with both the translocation and the dissociation were obtained when translocated and dissociated forms were crossed. In the F₁ of one cross a triploid clone with the autosomal 1,3 translocation was obtained.     

The Discovery of Diploid Lycoris radiata (L′Her.) Herb. from Anhui

Lycoris radiata (L′Her. ) Herb. containing wild and cultural types, is distributed in China and Japan. The karyotype variation in three populations of the species from Anhui is studied in this paper. (1) Wuhu wild population has a karyotype 2n=21+1B= 1m+12st +8t+1B. The chromosomes range in length from 7.50 to 14.10 µm with the ratio of the longest to the shortest 1.88. The karyotype belongs to Stebbins’(1971) 3A. (2) Huangshan wild population has two cytotypes: 2n=22 and 2n=22+1B. Type Ⅰ: The karyotype formula is 2n=22=12st+10t. The chromosomes range in length from 6.85 to 9.95 µm. with the ratio of the longest to the shortest 1.45. The karyotype belongs to 4A. Type Ⅱ: The karyotype formula is 2n=22+1B=6st+14t+2T+1B (plate 1: 7,8). The chromosomes range in length from 6.50 to 11.02 µm. with the ratio of the longest to the shortest 1.70. The karyotype belongs to 4A. (3) Wuhu cultural type has a karyotype 2n=33=30st +3t. The chromosomes range in length from 7.10 to 9.35 µm with the ratio of the longest to the shortest 1.32. The karyotype belongs to 4A. This result agrees well with the previous reports. The diploid types of Lycoris radiata (L´Her.) Herb. are found in Anhui for the firsttime.     

Additional chromosome in a child as a result of a balanced reciprocal translocation t(12;18)(p13;q12) in his mother's karyotype

In this case report we present a child with an additional chromosome in the karyotype. The karyotypes of the boy and his parents were analyzed by use of a conventional banding technique (GTG) and fluorescence in situ hybridization (FISH). Probes painting whole chromosomes 12 and 18 were used in FISH. Cytogenetic examination of the parents revealed that his mother was carrying balanced reciprocal translocation between chromosomes 12 and 18. Her karyotype was described as 46,XX,t(12;18)(p13;q12). Father's karyotype was normal, described as 46,XY. The boy's karyotype was defined as 47,XY,+der(18)t(12;18)(p13;q12). The additional chromosome appeared probably due to 3:1 meiotic disjunction of the maternal balanced translocation, known as tertiary trisomy. The mother displayed a normal phenotype and delivered earlier a healthy child. However, the boy with the unbalanced karyotype shows multiple congenital abnormalities.     

越南油茶的核型分析

<正> 越南油茶(Camellia vietnamensis T.C.Huang ex Hu)分布于我国广东和广西。越南油茶的种子油可供食用,为我国南方主要油料经济树种之一。越南油茶的染色体数目巳由黄少甫等同志报道过,2n=120,而核型分析方面的工作未见报道。