Target sites for SINE integration in Brassica genomes display nuclear matrix binding activity.

Short interspersed nuclear elements (SINEs) are ubiquitous components of complex animal and plant genomes. SINEs are believed to be important players in eukaryotic genome evolution. Studies on SINE integration sites have revealed non-random integration without strict nucleotide sequence requirements for the integration target, suggesting that the targeted DNA might assume specific secondary structures or protein associations. Here, we report that S1 SINE elements in the genomes of Brassica show an interesting preference for matrix attachment regions (MARs). Ten cloned genomic regions were tested for their ability to bind the nuclear matrix both before and after a SINE integration event. Eight of the genomic regions targeted by S1 display strong affinity for the nuclear matrix, while two show weaker binding. The SINE S1 did not display any matrix-binding capacity on its own in either non-methylated or methylated forms. In vivo, an integrated S1 is methylated while the surrounding genomic regions may remain undermethylated or undergo methylation. However, tested genomic regions containing methylated S1, with or without methylated flanking genomic sequences, were found to vary in their ability to bind the matrix in vitro. These results suggest a possible molecular basis for a preferential targeting of SINEs to MARs and a possible impact of the integration events upon gene and genome function.

Structural domains and matrix attachment regions along colinear chromosomal segments of maize and sorghum.

Although a gene's location can greatly influence its expression, genome sequencing has shown that orthologous genes may exist in very different environments in the genomes of closely related species. Four genes in the maize alcohol dehydrogenase (adh1) region represent solitary genes dispersed among large repetitive blocks, whereas the orthologous genes in sorghum are located in a different setting surrounded by low-copy-number DNAs. A specific class of DNA sequences, matrix attachment regions (MARs), was found to be in comparable positions in the two species, often flanking individual genes. If these MARs define structural domains, then the orthologous genes in maize and sorghum should experience similar chromatin environments. In addition, MARs were divided into two groups, based on the competitive affinity of their association with the matrix. The "durable" MARs retained matrix associations at the highest concentrations of competitor DNA. Most of the durable MARs mapped outside genes, defining the borders of putative chromatin loops. The "unstable" MARs lost their association with the matrix under similar competitor conditions and mapped mainly within introns. These results suggest that MARs possess both domain-defining and regulatory roles. Miniature inverted repeat transposable elements (MITEs) often were found on the same fragments as the MARs. Our studies showed that many MITEs can bind to isolated nuclear matrices, suggesting that MITEs may function as MARs in vivo.

Colinearity and its exceptions in orthologous adh regions of maize and sorghum.

Orthologous adh regions of the sorghum and maize genomes were sequenced and analyzed. Nine known or candidate genes, including adh1, were found in a 225-kilobase (kb) maize sequence. In a 78-kb space of sorghum, the nine homologues of the maize genes were identified in a colinear order, plus five additional genes. The major fraction of DNA in maize, occupying 166 kb (74%), is represented by 22 long terminal repeat (LTR) retrotransposons. About 6% of the sequence belongs to 33 miniature inverted-repeat transposable elements (MITEs), remnants of DNA transposons, 4 simple sequence repeats, and low-copy-number DNAs of unknown origin. In contrast, no LTR retroelements were detected in the orthologous sorghum region. The unconserved sorghum DNA is composed of 20 putative MITEs, transposon-like elements, 5 simple sequence repeats, and low-copy-number DNAs of unknown origin. No MITEs were discovered in the 166 kb of DNA occupied by the maize LTR retrotransposons. In both species, MITEs were found in the space between genes and inside introns, indicating specific insertion and/or retention for these elements. Two adjacent sorghum genes, including one gene missing in maize, had colinear homologues on Arabidopsis chromosome IV, suggesting two rearrangements in the sorghum and three in the maize genome in comparison to a four-gene region of Arabidopsis. Hence, multiple small rearrangements may be present even in largely colinear genomic regions. These studies revealed a much higher degree of diversity at a microstructural level than predicted by genetic mapping studies for closely related grass species, as well as for comparisons of monocots and dicots.