The binding motifs for Ac transposase are absolutely required for excision of Ds1 in maize

Molecular biology of maize Ac/Ds elements: an overview

Maize Activator (Ac) is one of the prototype transposable elements of the hAT transposon superfamily, members of which were identified in plants, fungi, and animals. The autonomous Ac and nonautonomous Dissociation (Ds) elements are mobilized by the single transposase protein encoded by Ac. To date Ac/Ds transposons were shown to be functional in approximately 20 plant species and have become the most widely used transposable elements for gene tagging and functional genomics approaches in plants. In this chapter we review the biology, regulation, and transposition mechanism of Ac/Ds elements in maize and heterologous plants. We discuss the parameters that are known to influence the functionality and transposition efficiency of Ac/Ds transposons and need to be considered when designing Ac transposase expression constructs and Ds elements for application in heterologous plant species.

The complete Ac/Ds transposon family of maize

Background

The nonautonomous maize Ds transposons can only move in the presence of the autonomous element Ac. They comprise a heterogeneous group that share 11-bp terminal inverted repeats (TIRs) and some subterminal repeats, but vary greatly in size and composition. Three classes of Ds elements can cause mutations: Ds-del, internal deletions of the 4.6-kb Ac element; Ds1, ~400-bp in size and sharing little homology with Ac, and Ds2, variably-sized elements containing about 0.5 kb from the Ac termini and unrelated internal sequences. Here, we analyze the entire complement of Ds-related sequences in the genome of the inbred B73 and ask whether additional classes of Ds-like (Ds-l) elements, not uncovered genetically, are mobilized by Ac. We also compare the makeup of Ds-related sequences in two maize inbreds of different origin.

Results

We found 903 elements with 11-bp Ac/Ds TIRs flanked by 8-bp target site duplications. Three resemble Ac, but carry small rearrangements. The others are much shorter, once extraneous insertions are removed. There are 331 Ds1 and 39 Ds2 elements, many of which are likely mobilized by Ac, and two novel classes of Ds-l elements. Ds-l3 elements lack subterminal homology with Ac, but carry transposase gene fragments, and represent decaying Ac elements. There are 44 such elements in B73. Ds-l4 elements share little similarity with Ac outside of the 11-bp TIR, have a modal length of ~1 kb, and carry filler DNA which, in a few cases, could be matched to gene fragments. Most Ds-related elements in B73 (486/903) fall in this class. None of the Ds-l elements tested responded to Ac. Only half of Ds insertion sites examined are shared between the inbreds B73 and W22.

Conclusions

The majority of Ds-related sequences in maize correspond to Ds-l elements that do not transpose in the presence of Ac. Unlike actively transposing elements, many Ds-l elements are inserted in repetitive DNA, where they probably become methylated and begin to decay. The filler DNA present in most elements is occasionally captured from genes, a rare feature in transposons of the hAT superfamily to which Ds belongs. Maize inbreds of different origin are highly polymorphic in their DNA transposon makeup.

Transposable elements as catalysts for chromosome rearrangements

Barbara McClintock first showed that transposable elements in maize can induce major chromosomal rearrangements, including duplications, deletions, inversions, and translocations. More recently, researchers have made significant progress in elucidating the mechanisms by which transposons can induce genome rearrangements. For the Ac/Ds transposable element system, rearrangements are generated when the termini of different elements are used as substrates for transposition. The resulting alternative transposition reaction directly generates a variety of rearrangements. The size and type of rearrangements produced depend on the location and orientation of transposon insertion. A single locus containing a pair of alternative transposition-competent elements can produce a virtually unlimited number of genome rearrangements. With a basic understanding of the mechanisms involved, researchers are beginning to utilize both naturally occurring and in vitro-generated configurations of transposable elements in order to manipulate chromosome structure.

Spatial configuration of transposable element Ac termini affects their ability to induce chromosomal breakage in maize

Composite or closely linked maize (Zea mays) Ac/Ds transposable elements can induce chromosome breakage, but the precise configurations of Ac/Ds elements that can lead to chromosome breakage are not completely defined. Here, we determined the structures and chromosome breakage properties of 15 maize p1 alleles: each allele contains a fixed fractured Ac (fAc) element and a closely linked full-length Ac at various flanking sites. Our results show that pairs of Ac/fAc elements in which the termini of different elements are in direct or reverse orientation can induce chromosome breakage. By contrast, no chromosome breakage is observed with alleles containing pairs of Ac/fAc elements in which the external termini of the paired elements can function as a macrotransposon. Among the structures that can lead to chromosome breaks, breakage frequency is inversely correlated with the distance between the interacting Ac/Ds termini. These results provide new insight into the mechanism of transposition-induced chromosome breakage, which is one outcome of the chromosome-restructuring ability of alternative transposition events.

The temperature-dependent change in methylation of the Antirrhinum transposon Tam3 is controlled by the activity of its transposase

The Antirrhinum majus transposon Tam3 undergoes low temperature-dependent transposition (LTDT). Growth at 15 degrees C permits transposition, whereas growth at 25 degrees C strongly suppresses it. The degree of Tam3 DNA methylation is altered somatically and positively correlated with growth temperature, an exceptional epigenetic system in plants. Using a Tam3-inactive line, we show that methylation change depends on Tam3 activity. Random binding site selection analysis and electrophoretic mobility shift assays revealed that the Tam3 transposase (TPase) binds to the major repeat in the subterminal regions of Tam3, the site showing the biggest temperature-dependent change in methylation state. Methylcytosines in the motif impair the binding ability of the TPase. Proteins in a nuclear extract from plants grown at 15 degrees C but not 25 degrees C bind to this motif in Tam3. The decrease in Tam3 DNA methylation at low temperature also requires cell division. Thus, TPase binding to Tam3 occurs only during growth at low temperature and immediately after DNA replication, resulting in a Tam3-specific decrease in methylation of transposon DNA. Consequently, the Tam3 methylation level in LTDT is regulated by Tam3 activity, which is dependent on the ability of its TPase to bind DNA and affected by growth temperature. Thus, the methylation/demethylation of Tam3 is the consequence, not the cause, of LTDT.

New transposable elements identified as insertions in rice transposon Tnr1

Tnr1 (235 bp long) is a transposable element in rice. Polymerase chain reactions (PCRs) done with a primer(s) that hybridizes to terminal inverted repeat sequences (TIRs) of Tnr1 detected new Tnr1 members with one or two insertions in rice genomes. Six identified insertion sequences (Tnr4, Tnr5, Tnr11, Tnr12, Tnr13 and RIRE9) did not have extensive homology to known transposable elements, rather they had structural features characteristic of transposable elements. Tnr4 (1767 bp long) had imperfect 64-bp TIRs and appeared to generate duplication of a 9-bp sequence at the target site. However, the TIR sequences were not homologous to those of known transposable elements, indicative that Tnr4 is a new transposable element. Tnr5 (209 bp long) had imperfect 46-bp TIRs and appeared to generate duplication of sequence TTA like that of some elements of the Tourist family. Tnr11 (811 bp long) had 73-bp TIRs with significant homology to those of Tnr1 and Stowaway and appeared to generate duplication of sequence TA, indicative that Tnr11 is a transposable element of the Tnr1/Stowaway family. Tnr12 (2426 bp long) carried perfect 9-bp TIRs, which began with 5'-CACTA- -3' from both ends and appeared to generate duplication of a 3-bp target sequence, indicative that Tnr12 is a transposable element of the En/Spm family. Tnr13 (347 bp long) had 31-bp TIRs and appeared to generate duplication of an 8-bp target sequence. Two sequences, one the transposon-like element Crackle, had partial homology in the Tnr13 ends. All five insertions appear to be defective elements derived from autonomous ones encoding the transposase gene. All had characteristic tandem repeat sequences which may be recognized by transposase. The sixth insertion sequence, named RIRE9 (3852 bp long), which begins with 5'-TG- -3' and ends with 5'- -CA-3', appeared to generate duplication of a 5-bp target sequence. These and other structural features indicate that this insertion is a solo LTR (long terminal repeat) of a retrotransposon. The transposable elements described above could be identified as insertions into Tnr1, which do not deleteriously affect the growth of rice cells.

The role of subterminal sites of transposable element Ds of Zea mays in excision

Transposition depends on DNA sequences located at or near the termini of the transposon. In the maize transposable element Ds, these sequences were studied by site-directed mutagenesis followed by a transient excision assay in Petunia protoplasts. The transposase-binding AAACGG motifs found in large numbers in the element are important, but none of them is in itself indispensable, for excision. However, mutation of an isolated motif at the 3' end considerably reduced excisability. The inverted termini were confirmed to be indispensable. Point mutations in regions outside the inverted termini of Ds and not located in the transposase-binding motifs had, in some cases, a pronounced effect on excision frequency. The implications of these findings are discussed.