植物转基因位置依赖性沉默与位置效应

植物基因组能够识别外源基因的出现及所整合的特异位置并产生相应反应,通过分析嘧啶甲基化的信号及模式,比较不同表达水平转基因的整合位点及基因组环境差异,植物转基因位置依赖性沉默和位置效应的机理得到进一步揭示;讨论了位置效应的研究方法和克服策略。     

Transgene Repeat Arrays Interact with Distant Heterochromatin and Cause Silencing in Cis and Trans

Tandem repeats of Drosophila transgenes can cause heterochromatic variegation for transgene expression in a copy-number and orientation-dependent manner. Here, we demonstrate different ways in which these transgene repeat arrays interact with other sequences at a distance, displaying properties identical to those of a naturally occurring block of interstitial heterochromatin. Arrays consisting of tandemly repeated white transgenes are strongly affected by proximity to constitutive heterochromatin. Moving an array closer to heterochromatin enhanced variegation, and enhancement was reverted by recombination of the array onto a normal sequence chromosome. Rearrangements that lack the array enhanced variegation of white on a homologue bearing the array. Therefore, silencing of white genes within a repeat array depends on its distance from heterochromatin of the same chromosome or of its paired homologue. In addition, white transgene arrays cause variegation of a nearby gene in cis, a hallmark of classical position-effect variegation. Such spreading of heterochromatic silencing correlates with array size. Finally, white transgene arrays cause pairing-dependent silencing of a non-variegating white insertion at the homologous position.     

Chromatin Structure,Heterochromatin, and Transposable Genetic Elements: Are These Teammates?

Gene content proved to be less than expected in completely sequenced eukaryotic genomes. Moreover, gene number differs only three times between such distant organisms as human and Drosophila. Hence it is likely that the essential functional and structural differences between the two species mostly depend on the regulation of gene activity than on the set and quality of genes themselves. New data demonstrate that changes in chromatin structure play a greater role in the fine gene activity regulation than considered before. R.B. Khesin had foreseen many chromatin functions that only recently came to be recognized. Khesin was interested in genome inconstancy over his last years. A higher content of several important chromosomal proteins was recently revealed in chromatin of transposable genetic elements (TGE). The possible role of TGE in chromatin organization in the nucleus is considered.     

Heterochromatin Protein 1 Deleted Chromo Domain Decreases Gene Silencing of Transgene in Mouse

The heterochromatin protein 1 (HP1) regulates epigenetic gene silencing by promoting and maintaining chromatin condensation. To decrease gene silencing, the chromo domain (CD) in the M31 (the main HP1 in mouse) was deleted by site-directed mutagenesis. Vector pcDNA3.1(+)/M31-DeltaCD, in which the M31-DeltaCD is driven by the CMV promoter, and vector pcDNA3.1(+)/P1A3-M31-DeltaCD, in which the M31-DeltaCD is driven by a goat ss-casein promoter were constructed. The former vector was transfected into a murine fibroblast cell line, which can express enhanced green fluorescent protein (EGFP). EGFP expression, which was determined by flow cytometric analysis, increased approximately 80% in the transfected cells. After injection of the latter vector into transgenic mouse mammary glands, which can express human clotting factor IX (hFIX), the hFIX expression level in the mouse milk increased approximately 40-60% and hFIX in one mouse milk was maintained at a high concentration for over 10 days.     

Heterochromatin,colchicine, and karyotype

Summary Species of Chilocorus differ in chromosome number owing to centric fusion of metacentric chromosomes. The concomitant loss of arms is tolerated because in all unfused chromosomes one arm is completely heterochromatic, the other euchromatic. Under the influence of colchicine, the arms of unfused and fused chromosomes contract differentially. Unless the distribution of heterochromatin is known, karyotype analysis is destined to failure.Contribution No. 1138, Forest Entomology and Pathology Branch, Department of Forestry, Ottawa, Canada.Dedicated to Professor H. Bauer on the occasion of his sixtieth birthday.     

Copy Number and Orientation Determine the Susceptibility of a Gene to Silencing by Nearby Heterochromatin in Drosophila

The classical phenomenon of position-effect variegation (PEV) is the mosaic expression that occurs when a chromosomal rearrangement moves a euchromatic gene near heterochromatin. A striking feature of this phenomenon is that genes far away from the junction with heterochromatin can be affected, as if the heterochromatic state ``spreads.'''' We have investigated classical PEV of a Drosophila brown transgene affected by a heterochromatic junction ~60 kb away. PEV was enhanced when the transgene was locally duplicated using P transposase. Successive rounds of P transposase mutagenesis and phenotypic selection produced a series of PEV alleles with differences in phenotype that depended on transgene copy number and orientation. As for other examples of classical PEV, nearby heterochromatin was required for gene silencing. Modifications of classical PEV by alterations at a single site are unexpected, and these observations contradict models for spreading that invoke propagation of heterochromatin along the chromosome. Rather, our results support a model in which local alterations affect the affinity of a gene region for nearby heterochromatin via homology-based pairing, suggesting an alternative explanation for this 65-year-old phenomenon.     

Heterochromatic Position Effect at the Rosy Locus of DROSOPHILA MELANOGASTER: Cytological, Genetic and Biochemical Characterization

This report describes cytological, genetic and biochemical studies designed to characterize two γ-radiation induced, apparent "underproducer" variants of the rosy locus (ry:3-52.0), ry^ps1149 and ry^ps11136. The following observations provide a compelling basis for their diagnosis as heterochromatic position effect variants. (1) They are associated with rearrangements that place heterochromatin adjacent to the rosy region of chromosome 3 (87D). (2) The effect of these mutations on rosy locus expression is subject to modification by abnormal Y chromosome content. (3) The rearrangement alters only the expression of the rosy allele on the same chromosome (cis-acting). (4) The Y chromosome modification is only on the position-affected allele's expression. (5) The recessive lethality associated with the rearrangements relate to specific rosy region vital loci, and for ry^{ps 11136}, the lethality is not Y chromosome modified. (6) The peptide product of the position-affected allele is qualitatively normal by several criteria. (7) Heterozygous deletion of 87E2-F2 is a suppressor of the rosy position effect. (8) The rosy position effect on XDH production may be assayed in whole larvae and larval fat body tissue as well as in adults.     

The Polycomb Repressive Complex 1 Protein BMI1 Is Required for Constitutive Heterochromatin Formation and Silencing in Mammalian Somatic Cells

The polycomb repressive complex 1 (PRC1), containing the core BMI1 and RING1A/B proteins, mono-ubiquitinylates histone H2A (H2A^ub) and is associated with silenced developmental genes at facultative heterochromatin. It is, however, assumed that the PRC1 is excluded from constitutive heterochromatin in somatic cells based on work performed on mouse embryonic stem cells and oocytes. We show here that BMI1 is required for constitutive heterochromatin formation and silencing in human and mouse somatic cells. BMI1 was highly enriched at intergenic and pericentric heterochromatin, co-immunoprecipitated with the architectural heterochromatin proteins HP1, DEK1, and ATRx, and was required for their localization. In contrast, BRCA1 localization was BMI1-independent and partially redundant with that of BMI1 for H2A^ub deposition, constitutive heterochromatin formation, and silencing. These observations suggest a dynamic and developmentally regulated model of PRC1 occupancy at constitutive heterochromatin, and where BMI1 function in somatic cells is to stabilize the repetitive genome.     

Heterochromatin,gene position effect and gene silencing

Genomes of higher eukaryotes consist of two types of chromatin: euchromatin and heterochromatin. Heterochromatin is densely packed material typically localized in telomeric and pericentric chromosome regions. Euchromatin transferred by chromosome rearrangements in the vicinity of heterochromatin is inactivated and acquires morphological properties of heterochromatin in the case of position effect variegation. One of the X chromosomes in mammal females and all paternal chromosome set in coccides become heterochromatic. The heterochromatic elements of the genome exhibit similar structural properties: genetic inactivation, compaction, late DNA replication at the S stage, and underrepresentation in somatic cells. The genetic inactivation and heterochromatin assembly are underlain by a specific genetic mechanism, silencing, which includes DNA methylation and posttranslational histone modification provided by the complex of nonhistone proteins. The state of silencing is inherited in cell generations. The same molecular mechanisms of silencing shared by all types of heterochromatic regions, be it unique or highly repetitive sequences, suggest the similar organization of these regions. No type of heterochromatin is a permanent structure as they all are formed at the strictly definite stages of early embryogenesis. Based on the bulk of evidence accumulated today, heterochromatin can be regarded as a morphological manifestation of genetic silencing.     

异染色质及基因关闭

异染色质普遍存在于真核生物的染色质中,和细胞分裂、生存竞争等有密切关系,尤其在调节基因的活性上有重要作用。组蛋白尾的修饰,决定着异染色质的形成和解聚,从而控制基因的启闭,这一机制被称为组蛋白密码。本文以裂殖酵母的交配型区为例介绍了异染色质的的形成及维持机理。组蛋白密码可能是DNA遗传密码外生命的又一调节机制,而对异染色质形成和结构功能的研究,将成为破译组蛋白密码的钥匙。     

Heterochromatin structure and function

Although heterochromatin has long been used as a model for studying chromatin condensation and heritable gene silencing, it is only relatively recently that detailed information has become available on the mechanisms that underlie its structure. Current evidence suggests that these operate on at least three different levels. A regular nucleosome array may facilitate packaging of the chromatin into a highly condensed configuration. Methylation of histone H3 lysine 9 and lysine 27 generates heterochromatin marks that are recognised through binding of heterochromatin proteins such as HP1. Finally, very recent studies using genetic and biochemical approaches have indicated that the RNAi machinery plays an important role in the formation of heterochromatin.     

Heterochromatin and histone phosphorylation

Histone phosphorylation and nuclear structure have been compared in cultured cell lines of two related species of deer mice, Peromyscus crinitus and Peromyscus eremicus, which differ greatly in their heterochromatin contents but which contain essentially the same euchromatin content. Flow microfluorometry measurements indicated that P. eremicus contained 36% more DNA than did P. crinitus, and C-band chromosome staining indicated that the extra DNA of P. eremicus existed as constitutive heterochromatin. Two striking differences in interphase nuclear structure were observed by electron microscopy. Peromyscus crinitus nuclei contained small clumps of heterochromatin and a loose, amorphous nucleolus, while P. eremicus nuclei contained large, dense clumps of heterochromatin and a densely structured, well defined, nucleolonema form of nucleolus. Incorporation of ³²PO₄ into histones indicated that the steady-state phosphorylation of H1 was identical in P. crinitus and P. eremicus cells. In contrast, the phosphorylation rate of H2a was 58% greater in the highly heterochromatic chromatin of P. eremicus cells than in the lesser heterochromatic chromatin of P. crinitus cells, suggesting an involvement of H2a phosphorylation in heterochromatin structure. It is suggested that the three histone phosphorylations related to cell growth (H1, H2a, and H3) may be associated with different levels of chromatin organization: H1 interphase phosphorylation with some submicroscopic (molecular) level of organization, H2a phosphorylation with a higher level of chromatin organization found in heterochromatin, and H3 and H1 superphosphorylation with the highest level of chromatin organization observed in condensed chromosomes.