核基质结合区在转基因烟草中对转基因表达的影响

为研究核基质结合区 (matrixattachmentregions,MARs)在转基因植物中对外源转基因 (transgene)表达的影响 ,将来源豌豆 (PisumsativumL .)的MARs序列构建在报告基因 β_葡糖醛酸酶 (β_glucuronidase ,GUS)基因 (uidA)的两侧形成植物表达载体。将此载体与不包含MARs序列的植物表达载体经根癌土壤杆菌 (Agrobacteriumtumefaciens(SmithetTownsend)Conn)介导转化烟草 (NicotianatabacumL .)。GUS活性检测表明 ,MARs可以提高外源uidA基因的表达水平。和不包含MARs的转化植株相比 ,MARs序列的存在可以使uidA基因的平均表达水平提高 2倍 ,最高的可达 5倍     

玉米核基质结合区在烟草中对外源转基因表达水平的影响

为研究核基质结合区 (matrixattachmentregion ,MAR)在转基因植物中的功能 ,将来自玉米基因组的MAR序列构建在植物表达载体T_DNA中 ,并将报告基因β_葡糖醛酸酶 (β_glucuronidase ,GUS)基因 (uidA)插入两段MARs序列之间。将此载体与不包含MARs序列的植物表达载体分别转化烟草 (NicotianatabacumL .)。GUS活性检测表明 ,MARs可以显著提高外源基因uidA在转基因烟草中的表达水平 ,平均表达水平提高 2倍 ,最高单株活性可达 10倍。并且转基因植株GUS活性高低与稳定mRNA的量成正比 ,表明MARs在转录水平提高基因表达。     

玉米核基质结合区在烟草中对外源转基因表达水平的影响

为研究核基质结合区(matrix attachment region, MAR)在转基因植物中的功能,将来自玉米基因组的MAR序列构建在植物表达载体T-DNA中, 并将报告基因β-葡糖醛酸酶(β-glucuronidase, GUS)基因(uidA)插入两段MARs序列之间.将此载体与不包含MARs序列的植物表达载体分别转化烟草(Nicotiana tabacum L.).GUS活性检测表明,MARs可以显著提高外源基因uidA在转基因烟草中的表达水平,平均表达水平提高2倍,最高单株活性可达10倍.并且转基因植株GUS活性高低与稳定mRNA的量成正比,表明MARs在转录水平提高基因表达.     

核基质结合区与转基因沉默

核基质结合区(matrix attachment region,MAR)又叫支架附着区(scaffold attachment region,SAIL)是染色质被限制酶消化后仍与核基质或核骨架结合的DNA序列。转基因沉默主要发生在两个水平上,一是转录水平,二是在转录后水平。位置效应是引起转录水平基因沉默的重要因素。研究发现,用MAR构建的载体能够提高转基因的表达水平,能在一定程度上克服基因沉默．降低转基因在不同转基因系间的表达差异,增强外源基因表达的稳定性。     

核基质结构区在转基因烟草中对转基因表达的影响

为研究核基质结合区（matrix attachment regions,MARs）在转基因植物中对源转基因（transgene）表达的影响,将来源豌豆（Pisum sativum L.）的MARs序列构建在报告基因β－葡糖醛酸酶（β-glucuronidase,GUS）基因（uidA）的两侧形成植物表达载体。将此载体与不包含MARs序列的植物表达载体经根癌土壤杆菌（Agrobacterium tumefaciens(Smith et Townsend)Com）介导转化烟草（Nicotiana tabacum L.）。GUS活性检测表明,MARs可以提高外源uidA基因的表达水平,和不包含MARs的转化植株相比,MARs序列的存在可以使uidA基因的平均表达水平提高2倍高的可达5倍。     

核基质结合区对转爬山虎芪合酶基因烟草中产生白藜芦醇的作用

采用核基质结合区(MARs)来提高转芪合酶基因(STS)烟草(Nicotiana tabacum L.)中白藜芦醇产物的含量。MARs是细胞中能与核基质特异紧密结合的DNA片段,体外结合实验表明克隆自酵母的MARs序列能特异地与烟草核基质结合。芪合酶是白藜芦醇生物合成中的关键酶,用RT-PCR方法从川鄂爬山虎(Parthenocissus henryana(Hemsl.) Diels et Gilg)中克隆了与葡萄芪合酶基因有较高同源性的芪合酶编码区,将其置于CaMV35SW强启动子下,分别构建两侧带有MARs及不含MARs序列的表达载体,通过农杆菌介导转化烟草。Northern blot及HPLC等分析表明STS基因已整合至烟草染色体中并正常转录,且表达的外源芪合酶在烟草中可催化其底物合成白藜芦醇产物。与对照相比,MARs的存在使转芪合酶基因烟草中白藜芦醇的含量平均提高了约一倍。MARs在转芪合酶基因植物中的应用也为获得抗病性更强、白藜芦醇含量更高、更保健的转基因果蔬的研究奠定了基础。     

核基质结合区对转爬山虎芪合酶基因烟草中产生白藜芦醇的作用

采用核基质结合区(MARs)来提高转芪合酶基因(STS)烟草(Nicotianatabacum L.)中白藜芦醇产物的含量.MARs是细胞中能与核基质特异紧密结合的DNA片段,体外结合实验表明克隆自酵母的MARs序列能特异地与烟草核基质结合.芪合酶是白藜芦醇生物合成中的关键酶,用RT-PCR方法从川鄂爬山虎(Parthenocissus henryana(Hemsl.)Diels et Gilg)中克隆了与葡萄芪合酶基因有较高同源性的芪合酶编码区,将其置于CaMV35SΩ强启动子下,分别构建两侧带有MARs及不含MARs序列的表达载体,通过农杆菌介导转化烟草.Northern blot及HPLC等分析表明STS基因已整合至烟草染色体中并正常转录,且表达的外源芪合酶在烟草中可催化其底物合成白藜芦醇产物.与对照相比,MARs的存在使转芪合酶基因烟草中白藜芦醇的含量平均提高了约一倍.MARs在转芪合酶基因植物中的应用也为获得抗病性更强、白藜芦醇含量更高、更保健的转基因果蔬的研究奠定了基础.     

核基质结合区对转基因表达的影响及其作用机制

核基质结合区(matrix attachment region,MAR)是一段在体外能与核基质结合的富含AT的DNA序列。研究发现MAR能使染色质形成环状结构;将其连到目的基因二侧构建载体并转至生物体中,发现它能增强基因转录表达水平及稳定性,在一定程度上降低转基因个体或细胞系之间转基因的表达水平的差异,这很可能是减低了基因沉默所致。现对MAR的序列特征、MAR对转基因表达的影响及对转基因效应的影响机制进行综述。     

基质结合区（MARs）与转基因植物的基因表达

对动植物的研究结果表明,基质结合区（MARs）能提高转基因的表达水平,并能降低其在转基因个体之间的表达差异。本文着重综述了MARs的基本特征及其在转基因植物中的研究应用,对MARs在转基因动物方面的研究成果和MARs的作用机制也作了介绍。     

植物的MAR及其对转基因表达的效应

与核基质结合的DNA序列称为基质附着区（matrix attachment regions,MARs）,可提高转基因的表达水平并降低转基因在不同转基因系间的表达差异,因其在植物基因工程中的巨大应用潜力而引起了研究者的极大兴趣。对植物中MAR的研究尚处于早期阶段,本文综述了植物中MAR的分离鉴定、序列特征及MAR对植物中转基因表达的影响,并进一步讨论了MAR对转基因效应的可能机制。 Abstract：DNA sequences called matrix attachment regions (MARs) have recently attracted mu ch attention because of their perceived capacity to increase levels of transgene expression and to reduce transformant-to-transformant variation of transgene ex pression in plants. Work with MARs in plants is in its early stage .In the prese nt paper ,we reviewed the procedure to isolate and identify MAR sequences from higher plants, the sequence characteristics of the plant MARs and the effect of MARs on the transgene expression in plants. Funthermore, the possible mechanism to explain how MARs affect transgene expression in transformants was discussed.     

Suppression of transgene silencing by matrix attachment regions in maize: a dual role for the maize 5' ADH1 matrix attachment region

Matrix attachment regions (MARs) are DNA sequences that bind an internal nuclear network of nonhistone proteins called the nuclear matrix. Thus, they may define discrete gene-containing chromatin loops in vivo. We have studied the effects of flanking transgenes with MARs on transgene expression levels in maize callus and in transformed maize plants. Three MAR elements, two from maize (Adh1 5' MAR and Mha1 5' MAR) and one from yeast (ARS1), had very different effects on transgene expression that bore no relation to their affinity for the nuclear matrix in vitro. In callus, two of the MAR elements (Adh1 5' MAR and ARS1) reduced transgene silencing but had no effect on the variability of expression. In transgenic plants, Adh1 5' MAR had the effect of localizing beta-glucuronidase expression to lateral root initiation sites. A possible model accounting for the function of Adh1 5' MAR is discussed.     

A short synthetic MAR positively affects transgene expression in rice and Arabidopsis

Matrix Attachment Regions (MARs) are DNA elements that are thought to influence gene expression by anchoring active chromatin domains to the nuclear matrix. When flanking a construct in transgenic plants, MARs could be useful for enhancing transgene expression. Naturally occurring MARs have a number of sequence features and DNA elements in common, and using different subsets of these sequence elements, three independent synthetic MARs were created. Although short, these MARs were able to bind nuclear scaffold preparations with an affinity equal to or greater than naturally occurring plant MARs. One synthetic MAR was extensively tested for its effect on transgene expression, using different MAR orientations, plant promoters, transformation methods and plant species. This MAR was able to increase average transgene expression and produced integration patterns of lower complexity. These data show the potential of making well defined synthetic MARs and using them to improve transgene expression.     

Use of matrix attachment regions (MARs) to minimize transgene silencing

Matrix attachment regions (MARs) are operationally defined as DNA elements that bind specifically to the nuclear matrix in vitro. It is possible, although unproven, that they also mediate binding of chromatin to the nuclear matrix in vivo and alter the topology of the genome in interphase nuclei. When MARs are positioned on either side of a transgene their presence usually results in higher and more stable expression in transgenic plants or cell lines, most likely by minimizing gene silencing. Our review explores current data and presents several plausible models to explain MAR effects on transgene expression.     

Epigenetic regulatory elements associate with specific histone modifications to prevent silencing of telomeric genes

In eukaryotic cells, transgene expression levels may be limited by an unfavourable chromatin structure at the integration site. Epigenetic regulators are DNA sequences which may protect transgenes from such position effect. We evaluated different epigenetic regulators for their ability to protect transgene expression at telomeres, which are commonly associated to low or inconsistent expression because of their repressive chromatin environment. Although to variable extents, matrix attachment regions (MARs), ubiquitous chromatin opening element (UCOE) and the chicken cHS4 insulator acted as barrier elements, protecting a telomeric-distal transgene from silencing. MARs also increased the probability of silent gene reactivation in time-course experiments. Additionally, all MARs improved the level of expression in non-silenced cells, unlike other elements. MARs were associated to histone marks usually linked to actively expressed genes, especially acetylation of histone H3 and H4, suggesting that they may prevent the spread of silencing chromatin by imposing acetylation marks on nearby nucleosomes. Alternatively, an UCOE was found to act by preventing deposition of repressive chromatin marks. We conclude that epigenetic DNA elements used to enhance and stabilize transgene expression all have specific epigenetic signature that might be at the basis of their mode of action.     

核基质结合序列（MAR）与基因表达调控

核基质结合序列（MAR）是能在体外与核基质特异结合的DNA序列,广泛存在于染色质Loop结构的边界序列中。随着研究的深入,发现MAR序列不仅在染色质折叠中起到重要作用,影响邻近内源基因表达,而且将MAR序列构建到外源基因表达盒两侧转化动植物时,也影响外源基因的表达。因此,MAR序列是基因组中一种重要的基因间边界序列,为阐明非编码序列在基因表达中的作用和构建真核生物高效表达载体提供了新途径。     

Increased expression of transgene in stably transformed cells of <Emphasis Type="Italic">Dunaliella salina</Emphasis> by matrix attachment regions

Nuclear matrix attachment regions (MARs) are known to bind specifically to the nuclear scaffold and are thought to influence expression of the transgenes. In our previous studies, a new deoxyribonucleic acid fragment isolated from Dunaliella salina could bind to the nuclear matrix in vitro and had the typical characteristics of MARs. In this study, to investigate effects of MARs on expression of transgenes in the stably transformed cells of D. salina, expression vectors with and without MARs, which contained chloramphenicol acetyltransferase (CAT) reporter gene driven by D. salina ribulose 1,5-bisphosphate carboxylase/oxygenase promoter, were constructed and delivered, respectively, into cells of D. salina by electroporation. Twenty stably transformed colonies of D. salina were randomly picked out, and CAT gene expression was assayed. The results showed that the CAT enzyme of the colonies of D. salina transformed with the expression vector containing MARs averaged out about 4.5-fold higher than those without MARs, while the transgene expression variation among individuals of transformants decreased threefold. The CAT enzyme in the stably transformed lines was not significantly proportional to the gene copy numbers, suggesting that the effects of MARs on transgene expression may not be through increasing the transgene copy numbers.     

Enhancement of maize transformation efficiency by the use of maize matrix attachment regions

Improving genetic transformation efficiency is a major concern in plant genetic engineering. While various strategies have been investigated, the enhancement of selectable marker gene expression has not been tried extensively. We used maize matrix attachment regions (MARs) to bracket an herbicide resistance transgene, bar. MARs have been reported to enhance transgene expression level and stability. We show here that MARs not only enhance transformation efficiency by 50%, but are also able to increase or decrease relative efficiencies of each step of the regeneration process depending on MAR sequence combinations. Furthermore, we assessed the trans-effect of MARs in co-bombardment experiments with two independent plasmids, one including the MAR sequences and the other one the bar gene. As for simple bombardment, MARs enhanced transformation efficiency by having a positive influence on organogenesis step in the regeneration process.