Scaffold attachment regions increase reporter gene expression in stably transformed plant cells.

The yeast ARS-1 element contains a scaffold attachment region (SAR) that we have previously shown can bind to plant nuclear scaffolds in vitro. To test effects on expression, constructs in which a chimeric beta-glucuronidase (GUS) gene was flanked by this element were delivered into tobacco suspension cells by microprojectile bombardment. In stably transformed cell lines, GUS activity averaged 12-fold higher (24-fold on a gene copy basis) for a construct containing two flanking SARs than for a control construct lacking SARs. Expression levels were not proportional to gene copy number, as would have been predicted if the element simply reduced position effect variation. Instead, the element appeared to reduce an inhibitory effect on expression in certain transformants containing multiple gene copies. The effect on expression appears to require chromosomal integration, because SAR constructs were only twofold more active than the controls in transient assays.     

A tobacco matrix attachment region reduces the loss of transgene expression in the progeny of transgenic tobacco plants

The RB7 matrix attachment region (MAR), when flanking a uidA (GUS) reporter gene, has been previously shown to increase uidA gene expression by 60-fold in stably transformed tobacco suspension cell lines. We have now used the same co-transformation procedure to determine the effect of flanking MARs on uidA gene expression in tobacco plants. The neomycin phosphotransferase selection gene and uidA reporter gene on separate plasmids were co-transformed into seedlings by microprojectile bombardment. In primary transgenic plants, the average uidA expression in plants with MARs was twofold greater than in control plants without MARs, but there was no effect on variation of expression. GUS activity was not proportional to the number of integrated uidA transgenes over the entire range of copy numbers. However, in the lower part of the copy number range, MAR lines show a tendency for expression to increase with copy number. Transgene expression in backcross progenies of the MAR-containing lines averaged threefold higher than in control progenies. MARs also reduced the loss of transgene expression in the BC₁ generation. Sixty-three per cent of the 21 MAR-containing primary transformants, but only 20% of the 14 control primary transformants, produced backcross progenies in which no loss of transgene expression was observed. These observations are discussed in the context of homology-dependent gene silencing.     

Transgene behaviour across two generations in a large random population of transgenic rice plants produced by particle bombardment

The relationship between transgene copy number, rearrangement levels, inheritance patterns, expression levels, transgene stability and plant fertility was analysed in a random population of 95 independently transformed rice plant lines. This analysis has been conducted for both the selectable marker gene ( aphIV) and the unselected reporter gene ( gusA), in the presence or absence of flanking Matrix Attachment Regions (MARs) in order to develop a better understanding of transgene behaviour in a population of transgenic rice plants created by particle bombardment. In the first generation (T(0)), all the independently transformed plant lines contained and expressed the aphIV gene conferring resistance to hygromycin, but only 87% of the lines were co-transformed with the unselected gusA marker gene. Both transgenes seemed to be expressed independently. Most lines exhibited complex transgene rearrangements as well as an intact transgene expression unit for both aphIV and gusA transgenes. Transgene copy number was proportional to the quantity of DNA used during bombardment. In T(0) plants, high gusA copy number significantly decreased GUS expression levels but there was no correlation between expression level and transgene copy number across the entire population of lines. Four main factors impaired transgene expression in primary transgenic plants (T(0)) and their progeny (T(1)): (1) absence of transgene expression in T(0) plants (41% of lines), (2) sterility of T(0) plants (28% of lines), (3) non-transmission of intact transgenes to some or all progenies (at least 14% of lines), and (4) silencing of transgene expression in progeny plants (10% of lines). Transgene stability was significantly related to differences in transgene structure and expression levels. The presence of Rb7 MARs flanking the gusA expression unit had no effect on plant fertility or non-transmission of transgenes, but provided copy number-dependent expression of the transgene and improved expression levels and stability over two generations. Overall, only 7% of the plant lines without MARs and 17% of the lines with MARs initially generated, exhibited stable transgene expression over two generations.     

Matrix attachment regions increase transgene expression levels and stability in transgenic rice plants and their progeny

To investigate the effect of matrix attachment regions (MARs) on transgene expression levels and stability in cereal crops, we generated 83 independent transgenic rice callus lines containing a gusA expression cassette either as a simple expression unit, or flanked with MARs from tobacco (Rb7) or yeast (ARS1). Transgenic rice plants were regenerated from these callus lines and analysed at the structural and expression levels over two generations. In the first generation (T₀), both Rb7 and ARS1 MARs significantly increased transgene expression levels. In the populations of plants containing MARs, we observed a significant reduction in the number of non-expressing lines compared to the population of plants without MARs. However, variation in β-glucuronidase (GUS) expression levels between independent lines was similar both in the presence and absence of flanking MARs. In the presence of MARs, GUS activity increased in proportion to transgene copy number up to 20 copies, but was generally reduced in lines carrying a higher copy number. In the population of plants without MARs, there was no correlation between expression level and transgene copy number. In the second generation (T₁), transgene expression levels were significantly correlated with those of the T₀ parents. The Rb7 MARs significantly improved the stability of transgene expression levels over two generations, and therefore appear to offer protection against transgene silencing. Our study shows that the exploitation of MARs may be an important strategy for stabilising transgene expression levels in genetically engineered cereals.     

Molecular characterization of the fate of transgenes in transformed wheat (Triticum aestivum L.)

Molecular analysis of the transgenes bar and gus was carried out over successive generations in six independent transgenic lines of wheat, until the plants attained homozygosity. Data on expression and integration of the transgenes is presented. Five of the lines were found to be stably transformed, duly transferring the transgenes to the next generation. The copy number of the transgenes varied from one to five in the different lines. One line was unstable, first losing expression of and then eliminating both the transgenes in R3 plants. Although the gus gene was detected in all the lines, GUS expression had been lost in R2 plants of all but one line. Rearrangement of transgene sequences was observed, but it had no effect on gene expression. All the stable lines were found to segregate for transgene activity in a Mendelian fashion.     

Co-silencing of homologous transgenes in tobacco

Two transgenes inserted into different genomic positions can co-inactivate each other when they share homologous sequences while each of the two homologous transgenes is stably expressed in the absence of a second homologous copy. To evaluate the efficiency of such homology-dependent gene silencing (HDGS) effects, we have produced 19 tobacco transformants that contained a stably expressed NPTII transgene inserted into a single genomic locus, and have analysed the stability of each transgene in the presence of a second stably expressed homologous transgene. All transformants shared the coding region of the NPTII gene but individual transformants differed in transgene copy number, expression levels and in the continuity of the transgene homology due to the insertion of introns into the NPTII region as well as the use of different promoters and terminators for the design of the transgene constructs. We generated 189 progeny populations representing all possible dual combinations among the 19 lines and analysed the kanamycin resistance of 400 seedlings of each cross. Our data show (1) that gene silencing occurs at a relative low frequency when transgenic loci sharing an homology at the coding sequence level are combined, and (2) that neither the variation of this homology by insertion of introns in the coding sequence, or by changing the promoter and terminator of the construct, nor the variation in the expression level of the transgene, are decisive parameters modifying the efficiency of co-silencing between two NPTII transgenes.