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(下)

我们创建了一个新的染色体模型:YR-黏和染色体模型,30nm螺线管通过JW-梯(或YR-梯)、染色线经螺旋化形成染色体[1].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。 Abstract:We provide a chromosome model YR-cohesion chromosome model.30nm solenoid fold and bent through JW-ladder and chromonema spiraling to chromosomeIll.It is checked by this calculation of picked ration,length,chromosomal structure and DNA base pairs,which are all consonant with practical resultsIll.YR-cohesion chromosome model will give a better answer to the questions such as exchange,centromere,holocentromere,synaptonemal complex,polytene chromosome,puff,lampbrush chromosome,chromosome banding,non-segregation of sister chromatid,pollentube pathway and biological evolution.     

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。     

果蝇多线染色体β异染色质区的螺旋结构(简报)

从1973年发现核小体至今,研究者们对染色质纤维结构和这种纤维组织成染色体的方式进行了广泛而深入的研究。由DNA到核小体到30nm染色质纤维几乎公认是按螺旋方式集缩的,但是有关30nm左右染色质纤维如何压缩形成染色体的高层次结构还没有统一的意见。关于这方面的研究目前已有许多模型。其中,Bak等提出的多级螺旋     

应用染色体涂染法建立人和黑叶猴(Semnopithecus francoisi)的染色体同源性

应用荧光原位杂交技术中的染色体涂染法（Chromosomepainting）,以生物素标记的除Y染色体外的人全部整条染色体DNA特异性探针与黑叶猴的中期分裂相杂交,建立了人与黑叶猴之间的染色体同源性。除人的1、2、6、16和19号染色体特异探针分别与黑叶猴的2条非同源的染色体杂交外,其余人染色体特异探针均与黑叶猴的1条染色体杂交,其中有两对人染色体特异探针（14和15,21和22）分别杂交同一条黑叶猴染色体。在雌性黑叶猴的单倍染色体中,共检测到30个与人染色体具同源性的染色体和染色体片段。结果表明：黑叶猴的多数染色体与人染色体有高度同源性,仅有少数染色体发生了重排。将研究的结果与已报道的人染色体特异探针与其他灵长类的中期染色体杂交的结果进行比较,可以看出亚洲叶猴之间的相互关系较与非洲叶猴的更为密切。     

人X染色体长臂(Xq)和短臂(Xp)基因组学比较分析

X染色体发生X染色体失活 ,但是Xp基因有 30 %表现为逃逸 ,而Xq仅不到 3%。为了研究X染色体基因失活和表达逃逸发生和维持的分子机制 ,比较了Xq和XpDNA序列的RNA模拟结合强度。X染色体的核苷酸序列被分为 5 0kb一段 ,对每一段DNA做 7碱基 (7nt)字符串组合分析 (共有 4 7=16 384种组合 ) ,记录每段 5 0kbDNA中每种 7nt字符串的频率。选择生发中心B细胞中的 12 0个高表达基因 ,计算这些基因的内含子 7nt字符串的出现频率 ,称为intron 7nt,以此作为RNAs(RNA群 ,模拟细胞中RNA在小片段的总和 )。已知一段DNA序列的 7nt频率值和intron 7nt,即可以计算该DNA段与intron 7nt的结合强度。每段 5 0kbDNA与intron 7nt的结合强度取决于该DNA段与intron 7nt互补核苷酸的频率 ,互补的核苷酸序列越多 ,结合强度就越大。DNA段与intron 7nt的模拟结合强度称为RNA结合强度 ,试图模拟该段DNA可以结合的RNA小片段的总量。之所以采用 7nt字符串组合分析是考虑到连续 7个核苷酸互补则可以形成相对稳定的结合。研究发现 :1)Xp各DNA段的RNA结合强度均值显著大于Xq (P <0 0 0 1) ;2 )Xp上高结合RNA的DNA段数目显著高于Xq (P <0 0 0 1) ;3)RNA高结合DNA段形成的簇与X染色体基因表达逃逸区关联。有证据表明 ,RNA可以通过改变染色质     

莲藕染色体上荧光原位杂交方法的初探

用酶解滴片法制备莲的染色体标本片,在传统的荧光原位杂交(FISH)的方法上进行改进,得到了一种适合于莲的高效荧光原位杂交方法,为莲的分子细胞遗传学研究提供技术上的帮助。     

小冰麦杂种落后染色体解凝聚过程的超微结构研究(简报)

70年代发现核小体以来,关于染色质和染色体的超微结构研究有了很大进展,对染色质的高序结构(Higher order structure)已提     

Chromosome scaffold and structural integrity of mitotic chromosomes

Chromosome scaffold represents a continuous protein substructure revealed in isolated metaphase chromosomes after harsh extraction. According to postulates of the widespread radial loop model the scaffold plays an important role in the formation and maintenance of structural integrity of the mitotic chromosomes. Here, the data concerning the structure and major components of the chromosome scaffold are presented. The experiments suggesting that the scaffold represents a system of discrete linker proteins and the data about high mobility of scaffolding proteins are discussed. Furthermore, the data about higher-level chromatin structures (elementary chromonema and 200–250 nm fibers) and behavior of scaffolding proteins are compared. The results presented agree with the idea that at the present stage it is possible to discriminate chromatin complexes, whose structural integrity is not maintained by the chromosome scaffold.     

Chromosome diversity of South American Oxalis (Oxalidaceae)

Mitotic or meiotic chromosome studies are reported for 39 species or subspecies of Oxalis from South America belonging to 14 sections. Chromosome numbers of 34 of these taxa are reported for the first time. Diploids and polyploids with six different basic chromosome numbers x=5, 6, 7, 8, 9 and 11 are described. Thirteen species of subgenus lhamnoxys were analysed and two new basic chromosome numbers were observed in diploid entities of this subgenus, x = 6 and x=9. The underground stem-bearing entities of Oxalis subgenus Oxalis studied (in sections Articulatae, Jonoxalis and Palmatifoliae) are mostly diploids and polyploids with a basic chromosome number x=7. Five species of section Carnosa are diploids with x = 9. In species of sections Rosea, Ortgieseae, Clematodes and Laxae the basic chromosome numbers x = 6, 7, 8 and 9 were observed. Groups of related species sharing the same chromosome number are discussed with the aim of improving the infrageneric delimitation of the genus. The basic chromosome number x=6 seems to be primitive in the genus and other basic chromosome numbers probably appeared several times in the course of chromosome evolution of Oxalis .     

Achiasmate Segregation of a B Chromosome from the X Chromosome in Two Species of Psyllids (Psylloidea, Homoptera)

The segregation of a B chromosome from the X chromosome was studied in male meiosis in two psyllid species, Rhinocola aceris (L.) and Psylla foersteri (Flor.) (Psylloidea, Homoptera). The frequency of segregation was determined from cells at metaphase II. In R. aceris, the B chromosome was mitotically stable and segregated quite regularly from the X chromosome in four geographically distant populations, while it showed less regular, but preferential segregation in one population. This was attributed to the presence of B chromosome variants that differ in their ability to interact with the X chromosome in segregation. In P. foersteri, the B chromosome was mitotically unstable and segregated preferentially from the X chromosome in spermatocyte cysts, which displayed one B chromosome in every cell. Behaviour of the B chromosome and X chromosome univalents during meiotic prophase and at metaphase I in R. aceris, and during anaphase I in P. foersteri suggested that the regular segregation resulted from the incorporation of B chromosomes in achiasmate segregation mechanisms with the X chromosome in the place occupied by the Y chromosome in species with XY system. The regular segregation of a B chromosome from the X chromosome may obscure the distinction of a B chromosome and an achiasmate Y chromosome in some cases. This revised version was published online in August 2006 with corrections to the Cover Date.     

染色质构象捕获及其衍生技术

染色质的构象在基因表达调节方面起重要作用．介绍了染色质构象捕获、环状染色质构象捕获、3C碳拷贝、ChIP-loop、ChIA-PET和Hi-C等技术的基本原理及发展历程,对影响实验结果准确性的主要因素进行了分析．目的是为在三维层面研究基因的表达调控介绍新的研究手段,为功能研究提供新思路,也为相关技术的应用提供理论参考．     

小麦—簇毛表6VS／6AL易位系可转化人工染色体（TAC）文库的构建

可转化人工染色体（Ｔｒａｎｓｆｏｒｍａｔｉｏｎ ｃｏｍｐｅｔｅｎｔ Ａｒｔｉｆｉｃｉａｌ Ｃｈｒｏｍｏｓｏｍｅ,ＴＡＣ）是具有克隆和转移大片段基因能力的新型载体,是植被基因克隆和转化的有效工具。为了克隆泪科抗白粉病基因和其它基因,本研究用ＴＣＡ载体ｐＹＬＴＡＣ１７构建了带有抗白粉病基因Ｐｍ２１的小麦＝簇毛麦６ＶＳ／６ＡＬ易位系的基因组ＤＮＡ文库。该文库包含２１０万个克隆平均插入征段３５ｌｂ,相当于     

基因组细菌人工染色体文库(BAC)的构建及应用

细菌人工染色体 (BAC)是一种承载DNA大片段的克隆载体系统 ,用于人、动物和植物基因组文库构建。BAC具有插入片断大、嵌合率低、遗传稳定性好、易于操作等优点。BAC文库的构建是基因组较大的真核生物基因组学研究的重要基础 ,可用于真核生物重要基因及全基因组物理作图、重要性状基因的图位克隆、基因结构及功能分析。本文主要综述了细菌人工染色体的构建与其鉴定 ,及其在物理图谱构建、图位克隆、转基因技术等研究上的应用。     

Structural-functional model of the mitotic chromosome

In the present review the structural role of noncoding DNA, mechanisms of differential staining of mitotic chromosomes, and structural organization of different levels of DNA compactization are discussed. A structural-functional model of the mitotic chromosome is proposed based on the principle of discreteness of structural levels of DNA compactization.     

二种木虱的染色体行为研究(同翅目:木虱总科)

报道了2种中国木虱的精子发生,即香椿巴木虱Bharatiana setentrionalis Yang et Li,n=7（XO）;合欢羞木虱Acizzia jamatonica（Kuwayama）,n=13（XO）。研究表明木虱的减数分裂具有3个显著的特征：1）前期I具有弥散期,此时常染色体疏松化,分散于整个细胞核,仅可以观察到异固缩化的性染色体,推测存在基因转录现象,同样的现象存在于蜡蝉和异翅类（Heteroptera）昆虫;2）中期Ⅰ姊妹染色体联合定向,第一次分裂为减数分裂;3）第二次分裂不发生胞质分裂,形成双核精子。从生殖系统的结构和减数分裂中染色体的行为来看,木虱与蜡蝉的关系更为密切。     

Chromosome numbers of Umbelliferae (Apiaceae) from Africa south of the Sahara

All previously reported chromosome counts for Umbelliferae of tropical and southern Africa are summarized, two from Socotra are included. New counts on 35 taxa in 14 genera are provided, mostly from Malawi or South Africa. Alepidea, Baumiella, Diplolophium, Lefebvrea , and Lichtenskinia are included for the first time.     

Chromosome numbers in the genus Lippia (Verbenaceae)

The genus Lippia (Verbenaceae) comprises about 200 taxa mainly distributed in Brazil, Mexico, Central America, Africa, Argentina and Paraguay. Some problems involving the number and delimitation of species have been reported. In order to contribute to the solving of these problems, the chromosome numbers of 14 Lippia species are documented. The following species were collected at Espinhaço Range, Southeast Brazil: Section Zapania (L. corymbosa, L. diamantinensis, L. hermannioides, L. lacunosa, L. rotundifolia, L. rubella), section Rhodolippia (L. florida, L. lupulina, L. pseudothea, L. rosella), section Goniostlachyum (L. glandulosa, L. pohliana, L. sidoides) and section Dioicolippia (L.filifolia). Immature inflorescences were collected and the ideal size for chromosome observation was determined. The majority of species have a haploid chromosome number from 10 to 14. Few species have a higher chromosome number, which suggests the occurrence of polyploidy. The relationships between chromosome numbers and the taxonomic sections are also discussed.