YR—黏和染色体模型初探（下）

我们刨建了一个新的染色体模型LYR－黏和染色体模型,30nm螺线管通过JW－梯（或YU－梯）、染色线经螺旋化形成染色体。通过包装比、长度的推算、染色体结构的推算、以及碱基对的推算都与实验观测值吻合,确认了YR－黏和模型的可信度。YR－染色体模型能自然、合理地解释所有遗传现象,如交换、着丝粒、全身着丝粒或弥散型着丝粒染色体、同源染色体联会及联会复合体的中央区、多线染色体与膨突、灯刷染色体、染色体分带、姊妹染色体由前期到中期不分开、花粉管会导入外源遗传物质、高等生命是怎样从原始生物进化而来的等等。     

YR-黏和染色体模型初探(上)

30nm螺线管是如何形成300nm染色线的?高度重复序列占人类第22号染色体DNA量的41.9％［1］,它们的功能是什么?全身着丝粒或弥散型着丝粒染色体是怎样形成的? 姐妹染色体由前期到中期为什么不分开?同源染色体联会是怎样形成的?联会复合体的中央区是什么?为什么通过花粉管会导入外源遗传物质?高等生命是怎样从原始生命进化而来的?在此,我们给出一个新的五级染色体模型：YR－黏和染色体模型。它不仅能解释以上问题,同时能解释多线染色体、灯刷染色体 以及一些经典遗传现象。 Abstract:How is the 300nm(nanometer)chromonema compacted with 30nm solenoid?What are the functions of repeat family sequence?How does the holocentromere or polycentromere chromosome form?What is the reason that non?separation of sister chromatid occur from prophase to metaphase?How do the synaptonemal complex(SC)occur?What are the compositions in the central region of SC?How to explain the transmission of heterologous?DNA by pollen tube pathway?How did the higher organism evolve from primitive forms?Hereon we provide a new five degree chromosome model-YR-cohesion chromosome model which will give a better answer to the questions above,as well as polytene chromosome,puff,and lampbrush chromosome and many other genetic phenomena.     

YR-黏和染色体模型初探(上)

30nm螺线管是如何形成300nm染色线的?高度重复序列占人类第22号染色体DNA量的41 9 % [1],它们的功能是什么?全身着丝粒或弥散型着丝粒染色体是怎样形成的?姐妹染色体由前期到中期为什么不分开?同源染色体联会是怎样形成的?联会复合体的中央区是什么?为什么通过花粉管会导入外源遗传物质?高等生命是怎样从原始生命进化而来的?在此,我们给出一个新的五级染色体模型 :YR -黏和染色体模型。它不仅能解释以上问题 ,同时能解释多线染色体、灯刷染色体以及一些经典遗传现象。     

羊驼染色体核型及其G分带的研究

为了从选种、杂交改良、疾病诊断以及性别决定的遗传机制等方面为羊驼的繁育与推广提供更为有效的细胞遗传学资料,本试验采用外周血淋巴细胞培养法及胰酶-EDTA法分析了23只胡阿基亚型羊驼（Huacaya alpaca,雌20只,雄3只）的染色体核型及其G-分带,结果表明：羊驼二倍体染色体数目为2n=74,雄性羊驼核型为74,XY;雌性羊驼核型为74,XX。其中,1～20对常染色体为亚端着丝粒染色体,21～36对常染色体为亚中着丝粒染色体和中着丝粒染色体,X为中着丝粒染色体,Y为端着丝粒染色体。G-带分析表明,羊驼G带明暗相间,显现出不同的带纹,且羊驼每对染色体都有其独特的带纹特征,其带纹数目和精细程度随着染色体长度的增加而增加。Abstract: Blood samples from 23 Huacaya alpacas, 3 males and 20 females, were used to study chromosomes and karyotypes, so as to provide some effective cytogenetic bases for the selection, improvement by crossing, disease diagnosis of alpacas, and genetic mechanisms of sex determination. Peripheral blood lymphocyte culture was used to prepare chromosome. A method of trypase-EDTA was used for G-banding. The results showed as follows: The number of diploid chromosomes was 2n=74, with the karyotype 74, XY and 74, XX for males and females respectively. Thirty-six homologous pairs of chromosomes were autosomes, in which chromosomes pairs No.1 to No.20 were acrocentric-subterminal and No.21 to No.36 metacentric-submetacentric. And X chromosome was metacentric, Y chromosome telocentric. The analysis of G-bands showed that bright and dark bands appeared by turn. It showed different bands. And every pair of chromosomes had its distinct band, and the longer the chromosomes, the more the number of bands, and the more clear the bands.     

赤链蛇染色体组型、C带和Ag-NORs的研究

以骨髓细胞为材料研究赤链蛇的染色体,结果表明该物种2n=46,由8对大型的和15对微小的染色体组成,AF=50.性染色体的大小介于3号和4号之间,为ZW型;8对大型染色体均显示着丝粒C带,1-6号还显示浅染端粒C带.W染色体为整条C带阳性;该物种一对NOR位于7号染色体近着丝粒区.不同地理分布群赤链蛇核型可能经历过Z与W染色体不等交换。 Abstract:The Karyotype,C-bands and Ag-NORs of Dinodon rufozonaturn (Cantor) reported is in this paper including the diploid number(2n=46)comprising 8 pairs of macro-and 15 pairs of microchromosomes,and AF=50 in the D.rufozonatum.The sex chromosome in size locates between the autochromosones No.3 and No.4,which belongs to ZW type.The C-banding technique revealed that the all macrochromosomes there are centromerc C band,the telomeric C band was only observed in Nos.1~6,while a whole W chromosome is constitutive heterochromatinization.Two NOR were observed on the pericentric of the No.7 chromosome.     

大鳞副泥鳅ZZ/ZW型性别决定的细胞遗传学证据

大鳞副泥鳅是鲤形目、鳅科的鱼类。其2n数为48,核型组成为12m+4sm+32 t(雄性),11m+5sm+32t(雌性)。根据银染带和C带特征分析,证实大鳞副泥鳅为ZZ/ZW型性别决定。Z染色体为中部着丝粒染色体,在其长臂端部有Ag -NOR存在。 W染色体为亚中部着丝粒染色体,在其长臂末端也有Ag-NOR存在,同时还有一深染的居间C带,这是W染色体独有的带纹特征。 Abstract:Paramisgurnus dabryanus belongs to Cypriniformes,Cobitidae.Its 2n is 48.The karyotype formula is 12m+4sm+32t(in male),11m+5sm+32t(in female).According to the Ag-NORs band and C-band patterns,we consider that its sex determination is of ZZ/ZW type.The Z chromosome is a metacentric one with Ag-NORs located on its arm end.The W chromosome is a submetacentric with Ag-NORs located on the terminal of its long arm.There is a darkly stained C-band on the long arm of W chromosome.This band is a characteric of the W chromosome.     

棕黑锦蛇赤峰亚种染色体组型、C带和Ag-NORs研究

以骨髓细胞为材料研究了棕黑锦蛇赤峰亚种的染色体, 结果表明,该物种的2n=36,由8对大型的和10对微小的染色体组成,AF=50。No.4为性染色体(ZW型);所有大型染色体均显示端粒深染C带,但仅NO.2、3、5和Z染色体显示着丝粒浅染C带。W染色体为整条C带阳性;该物种一对NOR分布于微小染色体。锦蛇属核型可能经历过染色体间的着丝粒融合的罗伯逊易位。 Abstract:This paper reports the karyotype,C-bands and Ag-NORs of Elaphe schrenckii anomala(Boulenger).The diploid number,2n=36,comprising 8 pairs of macro- and 10 pairs of microchromosomes in the E.s.anomala.AF=50.The No.4 is sex chromosome,which belong to ZW type.The C-banding technique revealed telomeric constitutive heterochromatin in the whole macrochromosome.But the centromeric C band was only observed in No.2,3,5 and Z chromosome,while a whole W chromosome is constitutive heterochromatinization.Two NORs was observed in group of microchromosome.     

Comparative analysis of chromosome segregation in human,yeasts and trypanosome

Chromosome segregation is a tightly regulated process through which duplicated genetic materials are equally partitioned into daughter cells. During the past decades, tremendous efforts have been made to understand the molecular mechanism of chromosome segregation using animals and yeasts as model systems. Recently, new insights into chromosome segregation have gradually emerged using trypanosome, an early branching parasitic protozoan, as a model organism. To uncover the unique aspects of chromosome segregation in trypanosome, which potentially could serve as new drug targets for anti-trypanosome chemotherapy, it is necessary to perform a comparative analysis of the chromosome segregation machinery between trypanosome and its human host. Here, we briefly review the current knowledge about chromosome segregation in human and Trypanosoma brucei, with a focus on the regulation of cohesin and securin degradation triggered by the activation of the anaphase promoting complex/cyclosome （APC/C）. We also include yeasts in our comparative analysis since some of the original discoveries were made using budding and fission yeasts as the model organisms and, therefore, these could provide hints about the evolution of the machinery. We highlight both common and unique features in these model systems and also provide perspectives for future research in trypanosome.     

对水稻第9和第12染色体编号分歧的细胞学考证

在水稻细胞遗传研究中, 对于染色体编号有着较多的争议,这在几条长度较短的染色体上显得尤为突出。为有比较地研究这几条染色体在水稻染色体组中的正确编号,本研究以涉及两条较短染色体相互易位的易位杂合体RT9-12为材料,分析了易位系与普通品种日本晴减数分裂粗线期染色体的形态特征。结果表明,该易位系的易位染色体并非第9和第12染色体,而是第10和第11染色体,从而认为目前国际上统一编号的第9、12染色体,根据染色体的实际长度可能分别为第10、11染色体。 Abstract:Rice chromosomes in mitosis are usually too small to be identified clearly one from others.In recent years,pachytene chromosomes in meiosis have been in vestigated intensively for establishing unified numbering system.However,divergence in numbering system is still existing especially for some short chromosomes such as chromosome 9 and 12.In order to verify these chromosomes,a translocation line RT9-12 and a japonica variety Nipponbare were carefully investigated for all the chromosomes morphologically in late pachytene stage.It was found that the chromosomes involved in translocation were chromosome 10 and 11 in stead of chromosome 9 and 12 as being compared with the karyotype of Nipponbare.So we consider that the chromosome 9 and 12 in the present rice chromosome numbering system could be chromosome 10 and 11 according to their length,arm ratio and the relationship with nucleolus.     

Characters of DNA constitution in the rye B chromosome

We have used chromosome microdissection and microcloning to construct a DNA library of the entire B chromosome （B） of rye. New rye B-specific sequences have been screened from this pool, blasted with other sequences and analyzed to elucidate the characters of DNA constitution and the possible pathway of the origin of the rye B chromosome. We report the discovery of a new sequence that is specific to the rye B centromere.     

玉米cyclinⅢ基因的染色体原位杂交物理定位

本文首次报道了玉米低拷贝基因 cyclinⅢ(B-类)生物素标记的染色体原位杂交定位结果。供试探针为该基因的cDNA克隆,其长度仅为1.6kb。结果表明, 探针的信号分布在第6染色体短臂和第9染色体长臂,与着丝粒的百分距离分别为70.05±3.31和86.86±1.64,检出率分别为8.29%和6.83%。文中对基因的物理位置与功能间的关系等作了讨论。 Abstract:A biotin-labelled in situ hybridization technique was used to physically map a low copy gene cyclinIII in maize.The cDNA clone was 1.7kb in size.The probe was hybridized onto the short arm of chromosome 6 and the long arm of chromosome 9.The percent distances from centromere to detection site were 70.05±3.31 and 86.86±1.64 respetively.The detection rates of in situ hybridization were 8.29 and 6.83 respectively,The relationship between the position and function of the genes is discussed in this paper.     

恶性血液病中着丝粒和着丝粒周染色体重排的研究进展

用染色体特异的卫星DNA探针进行染色体荧光原位杂交(FISH)分析恶性血液病,发现着丝粒和着丝粒周染色体的重排并非罕见.分子生物学技术和基因组计划的发展,促进了对异染色质分子本质的研究.本文就着丝粒和着丝粒周异染色质的分子结构及其重排机制作一综述。 Abstract:Fluorescence in situ hybridization(FISH) analysis with chromosome-specific satellite DNA probes of various hematopoietie malignancies have revealed that centric and pericentric chromosome rearrangements occurred more frequently than hitherto admitted.The development of molecular biology and genome project have fostered much interest in the structure and function of centromeric heterochromatin.In this paper,recent advances in molecular structure and rearrangement mechanisms of centric and pericentric heterochromatin are reviewed and future study is also discussed.     

泰和乌骨鸡的核型与带型研究

采用外周血淋巴细胞培养--空气干燥法,对泰和乌骨鸡染色体核型和带型进行了研究。结果表明：泰和乌骨鸡体细胞染色体数目2n=78,染色体基本臂数AF=90,1、9号染色体及Z、W性染色体为中央着丝粒（m）染色体,2、4、7号染色体为亚中央着丝粒（sm）染色体,3、6、8、10号染色体为端着丝粒（t）染色体。G带研究表明：前10对大型染色体可分为29个区,190条带。C带处理发现,所有母鸡分裂相中W性染色体都出现C带并整条深染。Ag-NORs研究发现：Ag-NORs常定位于1、2号常染色体短臂和Z性染色体短臂端部;Ag-NORs数目分布范围为1～6;平均每个细胞的Ag-NORs数在雌、雄鸡中分别为2.94和2.96。 Abstract:This study made the chromosome slides of Taihe Silkies by the peripheral blood lymphocyte culture-drying method,and analyzed Taihe Silkies karyotype and band pattern.The results are as follow:The diploid chromosome number of Taihe Silkies was 2n=78,the basic number of chromosome arms was AF=90 and the sex chromosome type was ZZ(♂)/ZW(♀).According to the measured relative length,arm ratio and centromeric index,the first 10 pairs of macro-chromosomes are described as follows:No.1 ,9 and Z,W chromosomes were metacentrics,No.2,4,7 were submetacentrics,and No.3,6,8,10 were telocentrics.Studies on Taihe Silkies′ G-band showed that the first 10 pairs of macro-chromosomes can be divided into 29 zones and 190 bands.Being treated by C-banding technique,a totally dark-stained and easily indentified W-chromosome always showed up in the female metaphase configurations.Ag-NORs were located in the short arms′ telomere of No.1,2 euchromosomes and Z sexchromosome,the Ag-NORs number varied from 1-6. -NORs     

染色体微切割、微分离、微克隆技术及其研究进展

自1981年染色体微切割及微克隆技术创建以来,该技术已广泛应用于人类及动植物遗传学、医学、进化学等研究领域,主要包括构建特定染色体或染色体区域的DNA文库、制备染色体描绘探针池以研究染色体重排和染色体进化等。本文对该技术的产生、发展及某些研究进展作一综述。 Abstract: Since chromosome microdissection and microcloning technique was developed in 1981,it has been wide ly used in genetics,medicine,evolution and other fields,mainly in establishing chromosome or chromosone specific region DNA libraries,preparing chromosome painting probe pools to study chromosome rearrangement and evolution.In the paper,the development and research progress of the technique are discussed.     

正常人胚胎绒毛细胞染色体着丝粒点(Cd)变异的研究

我们采用Cd-NOR同步银染技术,首次对正常人胚胎绒毛细胞染色体着丝粒点(Cd)变异作了研究,并将绒毛细胞染色体Cd变异与正常人外周血淋巴细胞体染色Cd变异进行了对比。在本研究中,我们观察到某些染色体存在Cd迟滞复制现象,并对此作了讨论。 Abstract:Centromeric dots(Cd)variation of chorion tissue chromosomes were studied by a simultaneous silver staining of both NOR and Cd.Comparison analysis of Cd variation for the chorionic villus samples and peripheral blood samples were carried out.We observe an event of Cd delaying reproduction and discuss the relation between the event and X chromosome delaying reproduction as well as chromosomeal nondisjunction.     

应用荧光原位杂交(FISH)技术研究 黑叶猴染色体易位

本文应用染色体荧光原位杂交(FISH)技术,利用人9号和14号染色体特异探针,对深低温冻存和长期传代的黑叶猴细胞株染色体畸变进行了分析。确定在长期冻存和传代过程中,一些黑叶猴细胞在No.12和No.17染色体之间发生了易位,一条 No.17染色体发生断裂,断裂点在17q13,断裂片段17q13-17qter易位到一条 No.12染色体长臂末端,形成一条小的中着丝粒的和一条具较长长臂的衍生染色体即 der(17) 和 der(12)。结果表明,荧光原位杂交技术用人染色体特异探针不仅能检测出人类染色体畸变,也能有效地检测灵长类动物染色体畸变。 Abstract　In this paper,the chromosome aberration of long-term cryopreserved and subcultured Francois' monkey (Semnopithecus francoisi) cell line(KCB 92008) was analyzed by fluoresence in situ hybridizaton (FISH) using human 9 and 14 chromosome DNA probes. After compared the hybridization pattern with the G-banding pattern on the same metaphase,a translocation between Nos.12 and 17 chromosomes was identified. In some Francois'monkey cells,one of chromosome No.17 was broken into two at the breakpoint 17q13,the segment(17q13-17qter) without centromere transfered to the long arm terminal of one chromosome No.12. Thus,two derivant chromosomes der(12) and der(17) were formed,the long arm of der(12) was longer than the normal partner,while the long arm of der(17) was shorter than the normal one. The result indicated that the technique of FISH using human whole chromosome probes was not only a powerful tool to detect human chromosome rearrangements,but also a usefulmethod to study the primate chromosome aberration.     

黑麂Y染色体的鉴别和Sry基因的克隆及定位

以流式细胞仪分离小麂(Muntiacus reevesi)Y染色体和黑麂(Muntiacus crinifrons)Y1,Y2,X+4和1号染色体,利用DOP-PCR技术富集了分离的各单条染色体。然后,将小麂的Y染色体的DOP-PCR产物经Cy3标记后直接作为涂染探针,应用染色体涂染技术与雌雄黑麂的核型标本进行杂交,确认了黑麂真正的Y染色体为Y2染色体。再以黑麂的Y1,Y2,X+4和1号染色体的DOP-PCR产物为模板,用人的特异性的SRY（sex determining region of the Y chromosome）基因引物对其进行扩增,结果表明黑麂只有Y2染色体出现了SRY扩增片段。然后扩增产物克隆和测序,比较它与人的同源性,初步把黑麂的Sry基因定位在Y2染色体上。最后提取雄性黑麂的基因组DNA,并用同一对引物对其进行扩增,亦得到Sry基因的片段,对此扩增片段进行克隆,测序,结果表明其与Y2染色体得到的Sry基因片段完全一样,与人SRY基因的同源性均为83%。 Abstract：The single Y chromosome of Muntiacus reevesi and Y1,Y2 ,X+4,1 chromosome of Muntiacus crinifrons were obtained by flow-sorting ,then they were amplified through DOP-PCR . After that, the metaphase karyotype of Muntiacus crinifrons were painted by using the product of the DOP-PCR of the Y chromosome of Muntiacus reevesi as a special probe and the result showed that Y2 chromosome was the real Y chromosome of Muntiacus crinifrons. Secondly the product of the DOP-PCR of Y1,Y2,X+4,1 chromosome of Muntiacus crinifrons were used as the templates of the next amplification using the special primer devised according to the human SRY gene .One band was obtained only from Y2 chromosome, then it was cloned to the T-vector and sequenced. The Sry gene sequence of Muntiacus crinifrons was acquired and the conclution was that there are 83% homology between the human and Muntiacus crinifrons. It was testified that in all mammal Sry gene is consertive. On the other side the Sry gene was located to the Y2 chromosome of the Muntiacus crinifrons.     

The Role of Chromatin Modifications in Progression through Mouse Meiotic Prophase

Meiosis is a key event in gametogenesis that generates new combinations of genetic information and is required to reduce the chro- mosome content of the gametes. Meiotic chromosomes undergo a number of specialised events during prophase to allow meiotic recombination, homologous chromosome synapsis and reductional chromosome segregation to occur. In mammalian cells, DNA phys- ically associates with histones to form chromatin, which can be modified by methylation, phosphorylation, ubiquitination and acetylation to help regulate higher order chromatin structure, gene expression, and chromosome organisation. Recent studies have identified some of the enzymes responsible for generating chromatin modifications in meiotic mammalian cells, and shown that these chromatin modifying enzymes are required for key meiosis-specific events that occur during meiotic prophase. This review will discuss the role of chromatin modifications in meiotic recombination, homologous chromosome synapsis and regulation of meiotic gene expression in mammals.     

应用染色体涂染技术分析两例染色体结构异常 Analysis of the Structure of Abnormal Karyotypes by Using Chromosome Painting

为了确定两例细胞遗传学提示染色体结构异常的核型,应用通过显微切割技 术构建的人类18号和7号染色体探针池,分别对这两例病例的中期分裂相进行染色体涂染,结合显带染色体,确定两者核型分别为46,XY,t(3;18) (q12;q21)和46,XX,dir ins(1;7)(p3104;q34q36)。染色体涂染技术是染色体显带技术的重要补充和发展,为染色体结构异常提供了一种直观、准确的检测手段,在遗传咨询和产前诊断方面有重要作用。 Abstract:In this study,chromosome painting technique was performed to analyse the abnormal karyotypes of two carriers.Chromosome 18 and 7 specific libraries,which were generated by chromosome microdissection technique,were used as probe pools to hybridize the carriers metaphase chromosomes respectively.Unlabled human genomic DNA was used to inhibit the hybridization of sequences in the library that bind to mutiple chromosomes.Structure abnormality was detected clearly in metaphase.Combined with the banding chromosomes,we concluded that their karytypes were 46,XY,t(3;18)(q12;q21)and 46,XX,dir ins(1;7)(p3104;q34q36).Chromosome painting,as a direct and concise method in analysing chromosome structure abnormality,is an important complement and development of chromosome banding technique,and has important application in genetic counselling and prenatal diagnosis.     

中华鳖精母细胞联会复合体的研究

本文以微铺展技术制备中华鳖精母细胞联会复合体标本,经硝酸银染色后电镜观察,分析了SC组型。并与有丝分裂染色体组型相比较,发现二者有着良好的一致性,而且微小染色体的SC结构和着丝粒清晰,未发现形态上有分化的性染色体。中华鳖SC的研究为其细胞遗传学及性别决定机制提供了重要的依据。 Abstract　Synaptonemal Complexes (SC) in Trionyx sinensis spermatocytes prepared with micro-spreading technique and silver staining was analyzed by electron microscopy. The meiotic SC karyotype was constructed from 10 cells and compared with mitotic chromosome karyotype. There is a good agreement between them. The structure and kinetochores of micro-chromosomes are very distinctive on each SC. There does not exist differential sex chromosome.