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.     

Elevation of Transgene Expression Level by Flanking Matrix Attachment Regions (MAR) is Promoter Dependent: A Study of the Interactions of Six Promoters with the RB7 3′ MAR

We have analyzed effects of a matrix attachment region (MAR) from the tobacco RB7 gene on transgene expression from six different promoters in stably transformed tobacco cell cultures. The presence of MARs flanking the transgene increased expression of constructs based on the constitutive CaMV 35S, NOS, and OCS promoters. Expression from an induced heat shock promoter was also increased and MARs did not cause expression in the absence of heat shock. There was also no effect of MARs on the pea ferredoxin promoter, which is not normally expressed in this cell line. Importantly, most transgenes flanked by RB7 MAR elements showed a large reduction in the number of low expressing GUS transformants relative to control constructs without MARs.     

Functional roles of the tyrosine within the NP(X)(n)Y motif and the cysteines in the C-terminal juxtamembrane region of the CB2 cannabinoid receptor

Sequence-dependent DNA conformations of matrix attachment regions (MARs) available in a database were calculated using the wedge model, and compared with randomly chosen genes, promoters, enhancers and transposons. The MARs had a longer bent part and higher angle/helical turn than the other regions. It is known that some MAR sequences have A-tracts that cause DNA bending, and we also found many A-tracts in examined MARs. Furthermore, non-random and clustered distribution of A-tracts shown here gave further evidence of the importance of A-tracts for MAR conformations. These results suggest that DNAs of MARs have a characteristic conformation instead of conserved sequence.     

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 matrix/scaffold attachment region binding protein: identification, purification, and mode of binding.

Matrix/scaffold attachment regions (MARs/SARs) partition chromatin into functional loop domains. Here we have identified a chicken protein that selectively binds to MARs from the chicken lysozyme locus and to MARs from Drosophila, mouse, and human genes. This protein, named ARBP (for attachment region binding protein), was purified to homogeneity and shown to bind to MARs in a cooperative fashion. ARBP is an abundant nuclear protein and a component of the internal nuclear network. Deletion mutants indicate that multiple AT-rich sequences, if contained in a minimal approximately 350 bp MAR fragment, can lead to efficient binding of ARBP. Furthermore, dimerization mutants show that, to bind ARBP efficiently, MAR sequences can act synergistically over large distances, apparently with the intervening DNA looping out. The binding characteristics of ARBP to MARs reproduce those of unfractionated matrix preparations, suggesting that ARBP is an important nuclear element for the generation of functional chromatin loops.     

Correlations between scaffold/matrix attachment region (S/MAR) binding activity and DNA duplex destabilization energy

Scaffold or matrix-attachment regions (S/MARs) are thought to be involved in the organization of eukaryotic chromosomes and in the regulation of several DNA functions. Their characteristics are conserved between plants and humans, and a variety of biological activities have been associated with them. The identification of S/MARs within genomic sequences has proved to be unexpectedly difficult, as they do not appear to have consensus sequences or sequence motifs associated with them. We have shown that S/MARs do share a characteristic structural property, they have a markedly high predicted propensity to undergo strand separation when placed under negative superhelical tension. This result agrees with experimental observations, that S/MARs contain base-unpairing regions (BURs). Here, we perform a quantitative evaluation of the association between the ease of stress-induced DNA duplex destabilization (SIDD) and S/MAR binding activity. We first use synthetic oligomers to investigate how the arrangement of localized unpairing elements within a base-unpairing region affects S/MAR binding. The organizational properties found in this way are applied to the investigation of correlations between specific measures of stress-induced duplex destabilization and the binding properties of naturally occurring S/MARs. For this purpose, we analyze S/MAR and non-S/MAR elements that have been derived from the human genome or from the tobacco genome. We find that S/MARs exhibit long regions of extensive destabilization. Moreover, quantitative measures of the SIDD attributes of these fragments calculated under uniform conditions are found to correlate very highly (r2>0.8) with their experimentally measured S/MAR-binding strengths. These results suggest that duplex destabilization may be involved in the mechanisms by which S/MARs function. They suggest also that SIDD properties may be incorporated into an improved computational strategy to search genomic DNA sequences for sites having the necessary attributes to function as S/MARs, and even to estimate their relative binding strengths.     

Chromosomal loop anchorage sites appear to be evolutionarily conserved

We have previously identified a class of DNA sequence elements, termed matrix association regions (MARs), which specifically bind to nuclear matrices in vitro and are believed to be at the bases of chromosomal loops in vivo. Here we demonstrate that nuclear matrices prepared from the yeast Saccharomyces cerevisiae will specifically bind an MAR sequence derived from the mouse kappa light chain immunoglobulin gene. This suggests that both MAR sequences and their binding sites have been strongly evolutionarily conserved.     

Effect of flanking matrix attachment regions on the expression of microinjected transgenes during preimplantation development of mouse embryos

The efficiency of transgenic animal production would increase if microinjected embryos with a successfully integrated transgene could be identified prior to transfer. It is possible to detect microinjected DNA in embryos. However, no reliable system is able to distinguish between transgenes merely present as extrachromosomal DNA and those that have been integrated into chromatin. The experiments reported here were designed to determine if the inclusion of matrix attachment regions (MARs) would enhance the efficiency of transgenic embryos identification using a selection scheme based on the expression of green fluorescent protein (GFP). Pronuclei of mouse embryos were microinjected with GFP reporter gene under the control of three different promoters and flanked or not by three different MAR elements. Transgene expression profiles were followed by direct visualization of GFP in cultured microinjected embryos. Embryos at different developmental stages were classified according to their GFP expression and groups with the same expression pattern were transferred into oviducts of pseudopregnant female mice. Fetuses were collected between days 12–15, and their genomic DNA was purified and analyzed to detect transgene integration. We did not find any statistically significant difference between the percentage of transgenic fetuses produced from GFP-positive or GFP-negative embryos transferred at 4-cell, morula, or blastocyst stage. However, when MAR elements were included in the construct, we found that GFP-positive embryos transferred at the 2-cell stage produced a significantly higher percentage of transgenic fetuses than GFP-negative embryos, but MAR sequences did not completely eliminate false positives.