异爪蝗属及雏蝗属部分种类染色体核型及C带带型分析研究(直翅目,蝗总科)

分析研究异爪蝗属Euchorthippus Tarb.2种和雏蝗属Chorthippus Fieb.5种的染色体核型及C带带型.结果表明,2个属在染色体数目、染色体组式、异染色质含量等方面都有明显的差异.属下种间在染色体数目、染色体组式、性别决定机制、着丝粒C带等方面有相同的特征,在染色体相对长度、异染色质含量等方面有差异.     

中国2种短鼻蝗染色体C带核型研究(蝗总科:癞蝗科)

染色体C带核型在物种鉴定、分类阶元间的比较及其系统演化关系的推断中是一个有用的指标,染色体组内C带分布位置、大小、数量及异染色质含量可以反映出属、种及种下阶元的细胞学异同.本研究报道了中国2种短鼻蝗--裴氏短鼻蝗Filchnerella beicki和宽顶短鼻蝗Filchnerella amplivertica的染色体C带核型.结果表明:2种短鼻蝗均为XO(♂)型性别决定机制;染色体组成均为2n ♂=19,染色体为端着丝粒染色体;在各染色体相对长度、C带的大小、位置和着色程度上又存在不同程度的差异,可以作为区分种的依据.     

中国两种波腿蝗（蝗总科：癞蝗科）染色体C带核型研究

报道中国两种波腿蝗的染色体C带核型,结果表明：红胫波腿蝗Asiotmethis zacharjini (Bei-Bienko, 1926) 2n ♂ =18, neo-X为亚中着丝粒染色体,其他均为近端着丝粒染色体,染色体除强染的着丝粒C带,S8染色体具强染端部C带带纹,neo-Y染色体还具有一条宽的弱染的近着丝粒端居间C带,性别决定机制是neo-XY ♂型,该种染色体组成和性别决定机制在我国癞蝗中为首次报道,蓝胫波腿蝗Asiotmethis jubatus (Uvarov, 1926) 2n＝19♂,均为近端着丝粒染色体,仅具有明显强染的着丝粒C带,性别决定机制是XO ♂型;两种波腿蝗的异染色质含量存在显著性差异（α=0.05）。     

中国台湾小车蝗属三新种及中国已知种检索表(直翅目,蝗总科,斑翅蝗科,斑翅蝗亚科)（英文）

记述了中国台湾小车蝗属Oedaleus Fieber,1853的3新种。新种夏氏小车蝗Oedaleus xiai sp.nov.前翅短,刚到达后足股节顶端,可同本属所有已知种相区别。新种高雄小车蝗Oedaleus kaohsiungensis sp.nov.与台湾小车蝗Oe.formosana(Shiraki,1910)近似,不同之处为后足股节内侧具黑色斑纹和后足胫节黄褐色,非红色。新种南投小车蝗Oedaleus nantouensis sp.nov.与台湾小车蝗Oe.formosana(Shiraki,1910)近似,不同之处为复眼较大,纵径等于眼下沟的长度;中胸腹板中隔很宽,最小宽度为长的1.8倍。新种南投小车蝗Oedaleus nantouensis sp.nov.与高雄小车蝗Oedaleus kaohsiungensis sp.nov.也近似,不同之处为后足股节下缘红色,后足胫节红色。列出了产于中国的小车蝗属13个种的检索表。模式标本存于自然科学博物馆,台中,台湾,中国。     

两种突颜蝗的染色体C带核型研究

采用染色体C分带技术初次对癞蝗科Pamphagidae中国特有的突颜蝗属Eotmethis B.-Bienko 2个种,即天祝突颜蝗E. tientsuensis (Chang)和景泰突颜蝗E.jintaiensis Xi et Zheng的精原细胞有丝分裂中期和初级精母细胞减数分裂中期（中期I）染色体C带核型进行了比较研究。结果表明: 2种突颜蝗的染色体基数、着丝粒位置及染色体分组形式相同,且与前人的研究结果基本吻合,反映了癞蝗科昆虫核型的稳定性。同时,2种突颜蝗染色体相对长度值较为接近;结构异染色质总含量没有明显差异;并且两者无论在精原细胞有丝分裂中期还是减数分裂中期I细胞,其3号、4号和X染色体上都显现深着色较大块的着丝粒C带, 9号染色体上都出现大块深着色的端部C带,2号染色体上都发生清晰的近中部居间C带,以上反映了2个种在系统发生上的亲缘关系。另外,2种突颜蝗在C带带型上的差异,在1号、7号、8号染色体上有不同程度的反映,尤其是对应的7号、8号染色体上着丝粒C带块的大小和强弱有明显变化。     

中国二种癞蝗染色体C带核型

染色体C带核型在物种鉴定、分类阶元间的比较及其系统演化关系的推断中是一个有用的指标,染色体组内C带分布位置、大小、数量及异染色质含量可以反映出属、种及种下阶元的细胞学异同。文章报道中国2种癞蝗——红缘疙蝗Pseudotmethis rubimarginis Li和准噶尔贝蝗Beybienkia songorica Tzyplenkov的染色体C带核型,结果表明:2种癞蝗均为XO(♂)型性别决定机制。染色体组成均为2n♂=19,染色体为端着丝粒染色体;在各染色体相对长度,C带的大小,位置和着色程度上又存在不同程度的差异,可以作为区分种的依据。     

雏蝗属与异爪蝗属二个近缘属蝗虫的染色体核型比较（直翅目：网翅蝗科）

采用常规染色体制片方法,对雏蝗属的模式种白边雏蝗Chorthippus albomarginatus(De Geer)和异爪蝗属的模式种素色异爪蝗Euchorthippus unicolor(Ikonnikov)的染色体核型进行了分析比较。结果表明,两种蝗虫的染色体数目均为2n(♂)=17=16+XO;常染色体为中部着丝粒(m,6条)和端部着丝粒(t,10条)两种类型,性染色体类型为端部着丝粒。二者的相似性显示出2属具有较近的亲缘关系,并且在进化过程中处于较近的发展阶段。但2种蝗虫的核型公式和染色体的相对长度组成则不相同,白边雏蝗K(2n,♂)=6m+11t=8L+4M+4S+XO;素色异爪蝗K(2n,♂)=6m+11t=8L+6M+2S+XO;且2种蝗虫性染色体的位次也有明显差别,白边雏蝗的性染色体为第9位,而素色异爪蝗则为第8位。由此看出,该2属的蝗虫存在的不同遗传特征。     

棉蝗的染色体组型和C带研究

本文研究了棉蝗(Chondracris roses rosea De Geer）的染色体组型和C带．结果表明：棉蝗的染色体数目：2n(♂）＝22十XO=23,全部为端着丝粒染色体,NF=23,核型公式：2n(♂）＝2X = 23t,按染色体长度顺序排列分成四组,但按相对程度也可分为三组;所有染色体都具有明显的着丝粒带;异染色质总量为15.94土0.26%;染色体组中最长与最短染色体之比为5.89 : l,臂比大于2:1的染色体比例为零,棉蝗的核型属"1C"核型．     

山稻蝗不同地域种群染色体C带核型研究

对我国分布的山稻蝗OxyaagavisaTsai不同种群进行了染色体C带核型研究 ,并对山稻蝗武夷山种群染色体C带核型进行了深入探讨 ,分析了其带型特殊性及该种群与其它山稻蝗种群染色体C带核型的区别与联系。同时通过对山稻蝗与中华稻蝗Oxyachinensis (Thunberg)、日本稻蝗Oxyajaponica (Thunberg)的形态、分布及染色体C带核型等方面的比较 ,探讨了该 3个种之间的进化关系 ,认为作为稻蝗属中的大型种类 ,上述 3个种之间有着较近的亲缘关系。染色体带型的实验结果表明 ,中华稻蝗为较原始的种类 ,而日本稻蝗和山稻蝗则可能是由原始中华稻蝗进化而来 ,其中日本稻蝗L2染色体的形成是由于原始中华稻蝗该染色体常染色质部分异染色质化的结果 ,山稻蝗L2染色体则可能是由于原始中华稻蝗该染色体近端部的臂间倒位所致。通过对武夷山山稻蝗的研究 ,对日本稻蝗和山稻蝗之间的近缘关系进行了分析和讨论。     

雏蝗属黑翅亚属两种雏蝗染色体核型的比较研究

采用常规染色体制片方法,对雏蝗属黑翅亚属的黑翅雏蝗(Chorthippus(Megaulacobothrus)aethalinus(Zub.))和中华雏蝗(Ch.(M.)chinensis Tarb.)的染色体核型进行了分析比较,结果表明,两种雏蝗的染色体数目均为2n(♂)=17=16+XO;常染色体为中部着丝粒(m,6条)和端部着丝粒(t,10条)两种类型,性染色体类型为端部着丝粒,二者的相似性显示出该属的基本特征。但两种雏蝗的核型公式和染色体的相对长度组成则不相同,黑翅雏蝗K(2n,♂)=6m+11t=6L+6M+4S+XO;中华雏蝗K(2n,♂)=6m+11t=6L+8M+2S+XO。而且,二种雏蝗的性染色体位次及相对长度也有明显差异:黑翅雏蝗的性染色体位于第五位,相对长度为8.33%,而中华雏蝗的则位于第八位,相对长度为5.53%。由此看出,二种雏蝗不同物种间存在的不同遗传特征。     

Polymorphism of heterochromatic regions of flax chromosomes

The C-banding technique was used to study flax chromosomes (Linum usitatissimum L., 2n = 30). Heterochromatin was located mainly in pericentromeric regions of chromosomes. In spite of small size (1.5-3.5 microm), all 15 pairs of homologous chromosomes were identified on the basis of the C-banding pattern and morphology. An idiogram of C-banded chromosomes of L usitatissimum L. is presented. Polymorphism of chromosomal heterochromatic regions was studied in karyotypes of three flax samples: L usitatissimum L., accession K-603 (L usitatissimum var. usitatissimum), and accession K-594 (L. usitatissimum var. humile (Mill.)). A common C-banding pattern was observed in all forms studied, although there were some distinctions in the individual band size. The fibre flax (accession K-603) karyotype had the C-banding pattern similar to that of L usitatissimum L., but some intercalary and telomeric C-bands were somewhat larger, and a satellite (NOR) was observed in the short arm of chromosome I. In crown flax, (K-594) chromosomal C-banding pattern exhibited smaller pericentromeric and larger intercalary bands; telomeric bands were present on almost all chromosomes. Thus, the intraspecies polymorphism revealed in the chromosomal C-banding pattern makes possible the use of C-bands as chromosome markers in the studies of genetic and genomic polymorphism of this species.     

Sequential chromosome banding and in situ hybridization analysis.

Different combinations of chromosome N- or C-banding with in situ hybridization (ISH) or genomic in situ hybridization (GISH) were sequentially performed on metaphase chromosomes of wheat. A modified N-banding-ISH/GISH sequential procedure gave best results. Similarly, a modified C-banding - ISH/GISH procedure also gave satisfactory results. The variation of the hot acid treatment in the standard chromosome N- or C-banding procedures was the major factor affecting the resolution of the subsequent ISH and GISH. By the sequential chromosome banding - ISH/GISH analysis, multicopy DNA sequences and the breakpoints of wheat-alien translocations were directly allocated to specific chromosomes of wheat. The sequential chromosome banding- ISH/GISH technique should be widely applicable in genome mapping, especially in cytogenetic and molecular mapping of heterochromatic and euchromatic regions of plant and animal chromosomes.     

河南花背蟾蜍的核型、C-带和Ag-NORs研究

利用骨髓细胞蒸汽固定法制备染色体标本,研究了分布于河南新乡的花背蟾蜍(Bufo raddei)的核型、C-带和Ag-NORs。结果表明：河南产花背蟾蜍体细胞染色体数为22条,核型公式为2n=22(20m 2sm),全部为中部或亚中部着丝点染色体,NF=44。Ag-NORs具有多态现象。C-带核型显示22条染色体的着丝点均正染,No．1染色体近着丝粒处有不恒定插入型C-带,No．4染色体具有恒定近端部插入型C-带,随体部位被正染的仅占所观察细胞的15％。     

小车蝗属Oedaleus Fieber昆虫的种间系统发育关系支序分析(直翅目:斑翅蝗科)

在已有比较形态学研究的基础上 ,本文选择了 1 9个性状 ,利用 PAUP程序 ,以支序分析探讨了小车蝗属昆虫的种间系统发育关系。结果红胫小车蝗 ( 1 )与黄胫小车蝗 ( 2 )的亲缘关系很近 ,是 1对姐妹群 ,亚洲小车蝗 ( 3)、黑条小车蝗 ( 4 )、红翅小车蝗( 5)、隆叉小车蝗 ( 6)这 4个种之间的相互关系比较近 ,它们的亲缘关系可表示为 :( ( ( 3,6) 4) 5) ,而台湾小车蝗 ( 7)与其它种类的亲缘关系均较远。     

毛百合根尖染色体Giemsa C-带分析

本研究利用Giemsa C-带方法对毛百合(Lilium dahuricum Ker-Gawl)根尖染色体进行了分析。研究结果表明毛百合试管苗的染色体倍性变异丰富,染色体倍性变异包括二倍体(2n=2×=24)、三倍体(2n=3×=36)、四倍体(2n=4×=48)到六倍体(2n=6×=72)。对二倍体毛百合的C-带结果进行分析,其带型公式为:2n=2×=24=2CI++2CI+T+T++6I+2I++2I++2I+T++2I+T++2I+T++2T++2T+。每条染色体上都显示出显著的特征带,而且带纹的深浅差异明显。强带主要集中在长短臂上。因此,GiemsaC-带方法可以将毛百合(L.dahuricum)的每条染色体区分开。     

A comparison of constitutive heterochromatin staining methods in two cases of familial heterochromatin deficiencies

Summary Using DAPI staining after pretreatment with distamycin A we detected a familial deficiency of chromosome 16 heterochromatin. A distinct positively staining band, however, was seen after C-banding. Thus, by using these different heterochromatin staining methods, heterogeneity of the constitutive heterochromatin in the centromeric region of human chromosome 16 was indicated. The same C-banding procedure was also applied to a previously described familial deficiency of chromosome 9 heterochromatin evidenced using distamycin A/DAPI staining and G 11 staining (Buys et al., 1979). In this case a C-band appeared to be virtually absent on the relevant chromosome. These staining methods may be valuable tools in the study of chromosome polymorphisms.     

应用原位杂交技术对小麦—黑麦代换系间杂交的细胞遗传研究

应用原位杂交技术结合染色体组型分析方法,对两个小麦-黑麦异源双代换系5R/5A和6R/6A杂交后代的遗传进行了研究,探讨同祖染色体配对的可能性并获得小麦-黑麦易位系。实验中对杂种F1代植株减数分裂各时期的花粉母细胞染色体行为进行分析,结果发现有22.91%的花粉母细胞中黑麦染色体与小麦染色体发生同祖配对。F2代通过C-分带、原位杂交鉴定,在45株中检测到9株易位,易位频率为20%,是目前报道易位频率最高的。染色体易位有的来源于同祖配对交换,有的来源于单价体错分裂或断裂的重建。     

Chromosome Markers in MUS MUSCULUS: Strain Differences in C-Banding

The mitotic chromosomes of several inbred strains of mice and a series of F(1) hybrids have been analyzed by quinacrine staining and further characterized by the centromeric heterochromatin banding (C-banding). Inbred strains had the same amount of C-banding material on homologous chromosomes but showed variation in the amount on different chromosomes. F(1) hybrids showed characteristics of each parent and it appears that the amount of C-banding on each chromosome is a simple inherited polymorphism. In this study 12 different chromosomes could be distinguished by their C-banding, and these can be used as normal chromosome markers.     

Standard Giemsa C-banded karyotype of Russian wildrye (Psathyrostachys juncea) and its use in identification of a deletion-translocation heterozygote.

Ten accessions of Russian wildrye, Psathyrostachys juncea (Fisch.) Nevski (2n = 2x = 14; NsNs), collected from different geographical regions were analyzed using the C-banding technique. C-banding pattern polymorphisms were observed at all levels, i.e., within homologous chromosome pairs of the same plant, among different individuals within accessions, between different accessions of the same geographic area, and among accessions of different origins. The seven homologous groups varied in the level of C-banding pattern polymorphism; chromosomes A, B, E, and F were more variable than chromosomes C, D, and G. The polymorphisms did not hamper chromosome identification in Ps. juncea, because each chromosome pair of the Ns genome had a different basic C-banding pattern and karyotypic character. A standard C-banded karyotype of Ps. juncea is proposed based on the overall karyotypes and C-bands in the 10 accessions. The C-bands on the Ns-genome chromosomes were designated according to the rules of nomenclature used in wheat. A deletion-translocation heterozygote of Russian wildrye was identified based on the karyotype and C-banding patterns established. The chromosome F pair consisted of a chromosome having the distal segment in the long arm deleted and a translocated chromosome having the distal segment of long arm replaced by the distal segment of the long arm of chromosome E. The chromosome E pair had a normal chromosome E and a translocated chromosome having the short arm and the proximal segment of the long arm of chromosome E and the distal segment of the long arm of chromosome F.     

Cytogenetic characterization of the bay scallop, Argopecten irradians irradians, by multiple staining techniques and fluorescence in situ hybridization

The chromosomes of Argopecten irradians irradians were studied by various cytogenetic approaches. Conventional chromosome characterization built on C-banding, DAPI-staining, and silver staining was complemented by the physical mapping of ribosomal DNA and telomeric sequence (TTAGGG)n by FISH. Results showed that the constitutive heterochromatin revealed by C-banding was mainly distributed at telomeric and centromeric regions. However, interstitial C-bands were also observed. The pattern of DAPI banding was almost consistent with that of C-banding. Silver staining revealed that NORs were located on the short arms of chromosome 3 and 10, and this was further confirmed by FISH using 18S-28S rDNA. 5S rDNA was mapped as two distinguishable loci on the long arm of chromosome 11. 18S-28S and 5S rDNA were located on different chromosomes by sequential FISH. FISH also showed that the vertebrate telomeric sequence (TTAGGG)n was located on both ends of each chromosome and no interstitial signals were detected. Sequential 18S-28S rDNA and (TTAGGG)n FISH demonstrated that repeated units of the two multicopy families were closely associated on the same chromosome pair.