Distribution of Unlinked Receptor Sites for Transposed Ac Elements from the Bz-M2(ac) Allele in Maize

We have shown before that the Ac element from the maize bz-m2(Ac) allele, located in the short arm of chromosome 9 (9S), transposes preferentially to sites that are linked to the bz donor locus. Yet, about half of the Ac transpositions recovered from bz-m2(Ac) are in receptor sites not linked to the donor locus. In this study, we have analyzed the distribution of those unlinked receptor sites. Thirty-seven transposed Ac (trAc) elements that recombined independently of the bz locus were mapped using a set of wx reciprocal translocations. We found that the distribution of unlinked receptor sites for trAs was not random. Ten trAcs mapped to 9L, i.e., Ac had transposed to sites physically, if not genetically, linked to the donor site. Among chromosomes other than 9, the Ac element of bz-m2(Ac) appeared to have transposed preferentially to certain chromosomes, such as 5 and 7, but infrequently to others, such as 1, the longest chromosome in the maize genome. The seven trAc elements in chromosome 5 were mapped relative to markers in 5S and 5L and localized to both arms of 5. We also investigated the transposition of Ac to the homolog of the donor chromosome. We found that Ac rarely transposes from bz-m2(Ac) to the homologous chromosome 9. The clustering of Ac receptor sites around the donor locus has been taken to mean that a physical association between the donor site and nearby receptor sites occurs during transposition. The preferential occurrence of 9L among chromosomes harboring unlinked receptor sites would be expected according to this model, since sites in 9L would tend to be physically closer to 9S than sites in other chromosomes. The nonrandom pattern seen among the remaining chromosomes could reflect an underlying nuclear architecture, i.e., an ordering of the chromosomes in the interphase nucleus, as suggested from previous cytological observations.     

The frequency of transposition of the maize element Activator is not affected by an adjacent deletion

Summary The maize mutable allele bz-m2 (Ac), which arose from insertion of the 4.6 kb Ac element in the bz (bronze) locus, gives rise to stable bz (bz-s) derivatives that retain an active Ac element closely linked to bz. In the derivative bz-s:2114 (Ac), the Ac element is recombinationally inseparable from bz and transposes to unlinked sites at a frequency similar to that in the progenitor allele bzm2 (Ac). Both alleles have been cloned and sequenced. The bz-s:2114 (Ac) mutation retains Ac at the original site of insertion, but has lost a 789 pb upstream bz sequence adjacent to the insertion, hence the stable phenotype. The 8 bp target site direct repeat flanking the Ac insertion in the bz-m2 (Ac) allele is deleted in bz-s: 2114 (Ac), yet the Ac element is not impaired in its ability to transpose. The only functional Ac element in bz-s:2114 (Ac) is the one at the bz locus: in second-cycle derivatives without Ac activity, the loss of Ac activity correlated with the physical loss of the Ac element from the bz locus. The deletion endpoint in bz-s: 2114 (Ac) corresponds exactly with the site of insertion of a Ds element in a different bz mutation, which suggests that there may be preferred integration sites in the genome and that the deletion originated as the consequence of an abortive transposition event. Finally, we report two errors in the published Ac sequence.     

Variable Patterns of Transposition of the Maize Element Activator in Tobacco

The strategy to be followed in a transposon tagging experiment will be determined largely by the transposition pattern of the transposon in question. With a view to utilizing the maize element Activator (Ac) as a transposon tag in heterologous systems, we investigated the pattern of Ac transposition from six different loci in transgenic tobacco. We isolated germinal revertants from plants carrying mutable alleles of the antibiotic-resistant gene streptomycin phosphotransferase (SPT) and mapped the location of the transposed Ac (trAc) elements relative to the donor SPT gene. A comparison of the distributions of trAcs among the six loci revealed that, although the receptor sites for trAcs tend to be linked to the donor locus, the pattern of Ac transposition in tobacco displays surprising locus-to-locus variation. Some trAc distributions showed the same tight clustering around the donor locus previously seen in maize, whereas others were more dispersed. The possible meaning of these findings and their implication for transposon tagging in heterologous systems are discussed.     

Transposition of Ac from the P Locus of Maize into Unreplicated Chromosomal Sites

We have analyzed donor and target sites of the mobile element Activator (Ac) that are altered as a result of somatic transposition from the P locus in maize. Previous genetic analysis has indicated that the two mitotic daughter lineages which result from Ac transposition from P differ in their Ac constitution at the P locus. Both lineages, however, usually contain transposed Ac elements which map to the same genetic position. Using methylation-sensitive restriction enzymes and genomic blot analysis, we identified Ac elements at both the donor P locus and Ac target sites and used this assay to clone the P locus and to identify transposed Ac elements. Daughter lineages were shown to be mitotic descendants from a single transposition event. When both lineages contained Ac genetic activity, they both contained a transposed Ac element on identical genomic fragments independent of the genetic position of the target site. This indicates that in the majority of cases, Ac transposition takes place after replication of the donor locus but before completion of replication at the target site.     

Genetic Fine Structure of the BRONZE Locus in Maize

The bronze (bz) locus in maize, located in the short arm of chromosome 9 (9S), is the structural gene for the anthocyanin biosynthetic enzyme UFGT. The gene has been cloned and its physical map has been oriented relative to the centromere of 9S. We report here the genetic fine structure mapping of several biochemically characterized EMS-induced bz-E mutations, derived from the Bz-W22 isoallele, and Ds insertion bz-m mutations, derived from the Bz-McC isoallele. Two UFGT(-), CRM(+ ) mutants (bz-E2 and bz-E5), which genetically identify coding sequences in the gene, and three UFGT(-), CRM(- )bz-E mutants were mapped against the Ds insertion mutants bz-m1 and bz-m2(DI) by selecting Bz intragenic recombinants from heterozygotes of the type bz-E/bz-m . The exclusive occurrence of one recombinant outside marker class allowed the unambiguous placement of the mutants in a genetic fine structure map. Peculiarly, the two CRM(+)bz-E mutants lie upstream of the three CRM(-)bz-E mutants and at a considerable genetic distance. The UFGT allozymes encoded by the progenitor alleles Bz-W22 and Bz-McC differ in two properties, thermal stability and activity. The sites responsible for these properties were mapped as unselected markers among the Bz intragenic recombinants. The thermal stability site, which also identifies a coding region of the gene, mapped very close to the CRM(+)bz-E mutant sites. The site responsible for variation in activity, which probably identifies a region involved in regulation of expression of the bz locus, mapped at the 5' or proximal end of the locus. It was found to be inseparable from the Ds insertion in bz-m1 that lies very close to the 5' end of the transcribed region.-Evidence was obtained that the insertion of Ds within the bz gene has a suppressing effect on intragenic recombination. Additional data are also presented supporting our observation that Ds affects the pattern of intragenic recombination at bz.-Based on the total genetic length of the bz gene and on the physical size of the transcribed region, we estimate that one unit of recombination at bronze corresponds to 14 kb of DNA. This estimate is more than 100 times smaller than the average value for the whole genome and implies that there may be regions, such as bronze, that serve as hotspots for recombination.     

Germinal Excisions of the Maize Transposon Activator Do Not Stimulate Meiotic Recombination or Homology-Dependent Repair at the Bz Locus

Double-strand breaks have been implicated both in the initiation of meiotic recombination in yeast and as intermediates in the transposition process of nonreplicative transposons. Some transposons of this class, notably P of Drosophila and Tc1 of Caenorhabditis elegans, promote a form of homology-dependent premeiotic gene conversion upon excision. In this work, we have looked for evidence of an interaction between Ac transposition and meiotic recombination at the bz locus in maize. We find that the frequency of meiotic recombination between homologues is not enhanced by the presence of Ac in one of the bz heteroalleles and, conversely, that the presence of a homologous sequence in either trans (homologous chromosome) or cis (tandem duplication) does not promote conversion of the Ac insertion site. However, a tandem duplication of the bz locus may be destabilized by the insertion of Ac. We discuss possible reasons for the lack of interaction between Ac excision and homologous meiotic recombination in maize.     

Molecular Analysis of Ac Transposition and DNA Replication

Molecular events associated with transposition of the mobile element Activator (Ac) from the P locus of maize have been examined in daughter lineages of twinned sectors. Genetic and molecular analyses indicate that the donor Ac has excised from only one of the two daughter chromosomes in these lineages. Cloning and sequence analyses of target sites on daughter chromosomes indicate that Ac insertion can occur either before or after the completion of DNA replication. Transpositions from a replicated donor site to both unreplicated and replicated target sites imply that most transpositions of Ac occur during or shortly after the S phase of the cell cycle.     

Distribution of Unlinked Transpositions of a Ds Element from a T-DNA Locus on Tomato Chromosome 4

In maize, receptor sites for unlinked transpositions of Activator (Ac) elements are not distributed randomly. To test whether the same is true in tomato, the receptor sites for a Dissociation (Ds) element derived from Ac, were mapped for 26 transpositions unlinked to a donor T-DNA locus on chromosome 4. Four independent transposed Dss mapped to sites on chromosome 4 genetically unlinked to the donor T-DNA, consistent with a preference for transposition to unlinked sites on the same chromosome as opposed to sites on other chromosomes. There was little preference among the nondonor chromosomes, except perhaps for chromosome 2, which carried seven transposed Dss, but these could not be proven to be independent. However, these data, when combined with those from other studies in tomato examining the distribution of transposed Acs or Dss among nondonor chromosomes, suggest there may be absolute preferences for transposition irrespective of the chromosomal location of the donor site. If true, transposition to nondonor chromosomes in tomato would differ from that in maize, where the preference seems to be determined by the spatial arrangement of chromosomes in the interphase nucleus. The tomato lines carrying Ds elements at known locations are available for targeted transposon tagging experiments.     

Use of the transposon Ac as a gene-searching engine in the maize genome

We show here that, although genes constitute only a small percentage of the maize genome, it is possible to identify them phenotypically as Ac receptor sites. Simple and efficient Ac transposition assays based on the well-studied endosperm markers bz and wx were used to generate a collection of >1300 independent Ac transposants. The majority of transposed Ac elements are linked to either the bz or the wx donor loci on chromosome 9. A few of the insertions produce obvious visible phenotypes, but most of them do not, suggesting that these populations will be more useful for reverse genetics than for forward transposon mutagenesis. An inverse polymerase chain reaction method was adapted for the isolation of DNA adjacent to the transposed Ac elements (tac sites). Most Ac insertions were into unique DNA. By sequencing tac sites and comparing the sequences to existing databases, insertions were identified in a number of putative maize genes. The expression of most of these genes was confirmed by RNA gel blot analysis. We report here the isolation and characterization of the first 46 tac sites from the two insertion libraries.     

Frequency and pattern of transposition of the maize transposable element Ds in transgenic rice plants

Two kinds of T-DNA constructs, I-RS/dAc-I-RS and Hm(R)Ds, carrying a non-autonomous transposable element of Ac of maize were introduced into rice plants by Agrobacterium-mediated gene transfer. Six transgenic rice plants identified as containing a single copy of the element were crossed with two transgenic rice plants carrying a gene for Ac transposase under the control of the cauliflower mosaic virus 35S promoter. In F2 progenies, excision of the element was detected by PCR analysis and re-integration of the element was investigated by Southern blot analysis. The frequency of the excision of the element was found to vary from 0 to 70% depending on the crossing combination. The frequency of the number of individual transposition events out of the total number of F2 plants with germinal excision was 44% in one crossing combination and 38% in the other. In the most efficient case, 10 plants with independent transposition were obtained out of the 49 F2 plants tested. Linkage analysis of the empty donor site and the transposed Ds-insertion site in F3 plants demonstrated that one of five Ds-insertion sites was not linked to the empty donor site. The transgenic rice obtained in this study can be used for functional genomics of rice.     

Characterization of an spm-controlled bronze-mutable allele in maize

The association of a receptor (Rs) of the Spm system with a Bz-1 allele has created a two-element Spm-controlled bz-mutable allele (bz-m13) of maize (Zea mays L.). In the absence of Spm, one copy of bz-m13 (bz/bz/bz-m13 ) conditions full anthocyanin production in the aleurone layer of the seed. In the presence of this Spm, bz-m13 produces a unique, coarsely variegated seed phenotype and has a high rate (50–83%) of gametic change to stable bz' or Bz' derivatives. Even one copy of a Bz' derivative allele conditions full anthocyanin production in the aleurone, but the enzyme (UFGT) level of the progenitor Bz-1 allele is not restored in most Bz' derivatives.     

Transposition of reversed Ac element ends generates chromosome rearrangements in maize

In classical "cut-and-paste" transposition, transposons are excised from donor sites and inserted at new locations. We have identified an alternative pathway in which transposition involves the 5' end of an intact Ac element and the 3' end of a nearby terminally deleted fAc (fractured Ac). The Ac and fAc elements are inserted at the maize p1 locus on chromosome 1s in the same orientation; the adjacent ends of the separate elements are thus in reversed orientation with respect to each other and are separated by a distance of approximately 13 kb. Transposition involving the two ends in reversed orientation generates inversions, deletions, and a novel type of local rearrangement. The rearrangement breakpoints are bounded by the characteristic footprint or target site duplications typical of Ac transposition reactions. These results demonstrate a new intramolecular transposition mechanism by which transposons can greatly impact genome evolution.     

Linked and Unlinked Transposition of a Genetically Marked Dissociation Element in Transgenic Tomato

We have introduced a genetically marked Dissociation transposable element (Ds(neo)) into tomato. In the presence of Ac transposase, Ds(neo) excised from an integrated T-DNA and reinserted at numerous new sites in the tomato genome. The marker genes of Ds(neo) (NPTII) and the T-DNA (HPT) facilitated identification of plants bearing transposon excisions and insertions. To explore the feasibility of gene tagging strategies in tomato using Ds(neo), we examined the genomic distribution of Ds(neo) receptor sites, relative to the location of the donor T-DNA locus. Restriction fragment length polymorphism mapping of transposed Ds(neo) elements was conducted in two tomato families, derived from independent primary transformants each bearing Ds(neo) within a T-DNA at a unique position in the genome. Transposition of Ds(neo) generated clusters of insertions that were positioned on several different tomato chromosomes. Ds(neo) insertions were often located on the same chromosome as the T-DNA donor site. However, no insertion showed tight linkage to the T-DNA. We consider the frequency and distance of Ds(neo) transposition observed in tomato to be well suited for transposon mutagenesis. Our study made use of a novel, stable allele of Ac (Ac3) that we discovered in transgenic tomato. We determined that the Ac3 element bears a deletion of the outermost 5 base pairs of the 5'-terminal inverted repeat. Though incapable of transposition itself, Ac3 retained the ability to mobilize Ds(neo). We conclude that a dual element system, composed of the stable Ac3 trans-activator in combination with Ds(neo), is an effective tool for transposon tagging experiments in tomato.     

Use of Ac as an insertional mutagen in Arabidopsis

A pilot-scale transposon mutagenesis experiment using a modified autonomous Activator (Ac) element, AcΔNael, was carried out in Arabidopsis thaliana. Four different transformants carrying Ac elements in different and defined genomic locations were used to generate 1000 plants carrying approximately 500 independent germinal transposition events. These plants were then selfed and the 1000 families screened in tissue culture and soil for phenotypic mutants. Fifty different families segregated mutations in their progeny. Preliminary Southern blot analysis of 29 families which segregated mutant progeny, showed that 28 had a transposed Ac. Six of the families were further tested for linkage between the transposed Ac and the mutant phenotype, and instability of the putatively tagged locus. Two of the mutants were shown to be tagged as they were tightly linked to a transposed Ac, and somatic and germinal reversion was associated with loss of Ac. One other mutant locus was shown to be closely linked to a transposed Ac, and therefore was likely to be tagged. The remaining three mutations were not tagged as they were not linked to a transposed Ac. In two of the tagged mutants Ac had transposed to closely linked sites, while in a third mutant the co-segregating Ac had transposed to a site which was not tightly linked to the donor T-DNA. Multiple insertions into the DIF1 locus were found, due to the preferential transposition of Ac to a linked site.     

Transposition patterns of unlinked transposed Ds elements from two T-DNA loci on tomato chromosomes 7 and 8

We have previously reported that unlinked transposed Ds elements originating from chromosome 4 of tomato preferentially inserted in chromosome 2. This observation, together with data from other studies, suggested that there may be absolute preferences for transposition, irrespective of the chromosomal location of the donor site. The aim of the present work was to verify whether the distribution of transposed Ds elements on chromosome 2 was non-random and thus whether, unlike the case in maize, unlinked transpositions in tomato are not distributed randomly. To do this, unlinked acceptor sites of Ds elements originating from two donor T-DNA loci lying on chromosomes 7 and 8 were mapped. Receptor sites for tr Ds elements transposed from the 1601D locus on chromosome 8 exhibited a non-random distribution (P<0.01). Eleven out of 46 independent transpositions mapped to chromosome 2 and, as this was statistically significant (P<0.01), proves that receptor sites for this element are not randomly distribution on the chromosomes. In addition, deviation of the observed number from the expected number of tr Dss was close to being significant for chromosome 4 (P=0.05-0.1). In contrast, the distribution of unlinked receptor sites for tr Dss derived from the 1481J locus on chromosome 7 was random. Chi(2)tests were performed for each chromosome, and for chromosome 4 the difference between the observed and the expected number of tr Dss was very high but statistically non-significant (P=0.05-0.1). For chromosome 2 the difference was statistically negligible. Therefore, we conclude that chromosome 2 does not serve as a preferential receptor for the transposition of Ds elements independently of the location of the donor site.     

Cloning of the Bz2 locus of Zea mays using the transposable element Ds as a gene tag

Summary The Bz2 locus of Zea mays has been cloned, utilizing the presence of the transposable element Dissociation (Ds) at the locus as a gene tag. The Ds element inserted in the bz2-m allele was identified among many members of the Ac/Ds family in a Southern blot analysis of a population segregating for bz2-m and Bz2. After cloning a DNA fragment from the bz2-m allele, sequences flanking the Ds insertion were shown to be Bz2-specific and were used to isolate a homologous fragment from a wild-type Bz2 line. The Ds insertion in the bz2-m allele was found to be a Ds2 element identical to the Ds insertion in adh1-2F11.     

Reconstitutional Mutagenesis of the Maize P Gene by Short-Range Ac Transpositions

The tendency for Ac to transpose over short intervals has been utilized to develop insertional mutagenesis and fine structure genetic mapping strategies in maize. We recovered excisions of Ac from the P gene and insertions into nearby chromosomal sites. These closely linked Ac elements reinserted into the P gene, reconstituting over 250 unstable variegated alleles. Reconstituted alleles condition a variety of variegation patterns that reflect the position and orientation of Ac within the P gene. Molecular mapping and DNA sequence analyses have shown that reinsertion sites are dispersed throughout a 12.3-kb chromosomal region in the promoter, exons and introns of the P gene, but in some regions insertions sites were clustered in a nonrandom fashion. Transposition profiles and target site sequence data obtained from these studies have revealed several features of Ac transposition including its preference for certain target sites. These results clearly demonstrate the tendency of Ac to transpose to nearby sites in both proximal and distal directions from the donor site. With minor modifications, reconstitutional mutagenesis should be applicable to many Ac-induced mutations in maize and in other plant species and can possibly be extended to other eukaryotic transposon systems as well.