Excision of Ds produces waxy proteins with a range of enzymatic activities.

The waxy (wx) locus of maize encodes an enzyme responsible for the synthesis of amylose in endosperm tissue. The phenotype of the Dissociation (Ds) insertion mutant wx-m1 is characterized by endosperm sectors that contain different levels of amylose. We have cloned the Wx gene from this allele and from two germinal derivatives, S5 and S9, that produce intermediate levels of amylose. The Ds insertion in wx-m1 is in exon sequences, is 409 bp in length and represents an example of a class of Ds elements that are not deletion derivatives of the Activator (Ac) controlling element. The two germinal derivatives, S5 and S9, lack the Ds element but contain an additional 9 and 6 bp, respectively, at the site of Ds insertion. The level of Wx mRNA and Wx protein in S5 and S9 is essentially the same as in normal endosperm tissue but Wx enzymatic activity is reduced. Thus, the lesions in S5 and S9 lead to the addition of amino acids in the Wx protein, resulting in Wx enzymes with altered specific activities. This work supports the notion that the maize transposable elements may serve a function in natural populations to generate genetic diversity, in this case, proteins with new enzymatic properties.     

Somatic Variegation and Germinal Mutability Reflect the Position of Transposable Element Dissociation within the Maize R Gene

The R gene regulates the timing and tissue-specificity of anthocyanin deposition during maize development. The Ac/Ds system of transposable elements was used to induce insertional mutants of the R-sc:124 allele during two cycles of mutagenesis. Of 43 unstable, spotted-aleurone mutants generated, 42 contain inserts of the Ds6 transposable element differing only in the position and orientation of the element. The remaining mutant, r-sc:m1, contained an insert of a Ds element of the approximate size of the Ds1 transposable element. The patterns of somatic variegation of these mutants, resulting from excision of Ds, define a spectrum of phenotypes ranging from sparse to dense variegation. The sparsely variegated mutants produce few germinal revertants but relatively many stable null derivative alleles; densely variegated mutants produce many germinal revertants and few stable null derivatives. Molecular analysis shows that the sparsely variegated alleles are caused by Ds6 insertions in protein coding regions of R-sc:124 whereas the densely variegated mutants result from insertions in introns or in flanking regions of the gene. The excision rate of Ds6 from R, estimated as the proportion of R genomic DNA restriction fragments lacking the element, was uniform regardless of position, orientation or whether the element was inserted in R-sc:124 or another R allele. The excision rate was greater, however, for the mutable alleles involving the Ds element from r-sc:m1. These data indicate that, although the excision rates are uniform for a given Ds element, the somatic and germinal mutability patterns of alleles associated with that element vary widely and depend primarily on the position of the transposable element within coding or noncoding regions of the gene.     

Molecular and physiological characterization of Arabidopsis GAI alleles obtained in targeted Ds-tagging experiments

Bioactive gibberellin (GA) is an essential regulator of vascular plant development. The GAI gene of Arabidopsis thaliana (L.) Heynh. encodes a product (GAI) that is involved in GA signalling. The dominant mutant gai allele encodes an altered product (gai) that confers reduced GA responses, dwarfism, and elevated endogenous GA levels. Recessive, presumed loss-of-function alleles of GAI confer normal height and resistance to the GA biosynthesis inhibitor paclobutrazol. One explanation for these observations is that GAI is a growth repressor whose activity is opposed by GA, whilst gai retains a constitutive repressor activity that is less affected by GA. Previously, we described gai-t6, a mutant allele which contains an insertion of a maize Ds transposable element into gai. Here we describe the molecular and physiological characterization of two further alleles (gai-t5, gai-t7) identified during the Ds mutagenesis experiment. These alleles confer paclobutrazol resistance and normal endogenous GA levels. Thus the phenotype conferred by gai-t5, gai-t6 and gai-t7 is not due to elevated GA levels, but is due to loss of gai, a constitutively active plant growth repressor.     

Heterologous transposon tagging of the DRL1 locus in Arabidopsis.

The development of heterologous transposon tagging systems has been an important objective for many laboratories. Here, we demonstrate the use of a Dissociation (Ds) derivative of the maize transposable element Activator (Ac) to tag the DRL1 locus of Arabidopsis. The drl1 mutant shows highly abnormal development with stunted roots, few root hairs, lanceolate leaves, and a highly enlarged, disorganized shoot apex that does not produce an inflorescence. The mutation was shown to be tightly linked to a transposed Ds, and somatic instability was observed in the presence of the transposase source. Some plants showing somatic reversion flowered and produced large numbers of wild-type progeny. These revertant progeny always inherited a DRL1 allele from which Ds had excised. Analysis of the changes in DNA sequence induced by the insertion and excision of the Ds element showed that they were typical of those induced by Ac and Ds in maize.     

Ac transposition is impaired by a small terminal deletion

In maize, the P1-vv allele specifies variegated pericarp and cob pigmentation, and contains an Ac transposable element inserted in the second intron of the P1-rr gene. Starting from P1-vv, we recovered a new allele, called P1-vv5145, which gives an extremely light variegated pericarp and cob phenotype. The P1-vv5145 allele contains an Ac element ( Ac5145) at the same position and in the same orientation as in the progenitor P1-vv allele; however, the P1-vv5145 allele has a 2-bp deletion which removes the last nucleotide (A) from the 3' end of the Ac element, and an adjacent flanking nucleotide (C) from the p1 intron. In crosses with a Ds tester stock, P1-vv5145 shows a normal ability to induce Ds transposition; however, Ac excision from P1-vv5145 is 3800-fold less frequent than from the progenitor P1-vv allele. Our results demonstrate that the alteration of the 3' terminal base strongly impairs Ac transposition. The P1-vv5145 allele thus provides a relatively stable source of Ac transposase for controlling Ds transposition in genetic experiments. In addition, we describe two further alleles ( P1-ww7B8, P1-ww9A146-3) that contain deletions of Ac and flanking p1 gene sequences. These latter deletions are larger and involve the 5' end of the the Ac element. A model is proposed to explain the formation of one-sided deletions as a consequence of Ac transposition during replication of the element.     

Transposon-mediated mutations in the untranslated leader of maize Adh1 that increase and decrease pollen-specific gene expression.

The unstable mutation Adh1-Fm335 contains a Dissociation (Ds1) transposable element at position +53 in the untranslated leader of the maize Alcohol dehydrogenase-1 (Adh1) gene. Excision of Ds1 is known to generate new alleles with small additions and rearrangements of Adh1 DNA. We characterized 16 revertant alleles with respect to ADH1 activity levels in scutellum (nutritive tissue of the seed), anaerobic root, and pollen. Whereas gene expression was not different from the wild type in the sporophytic tissues of the scutellum and anaerobic root, there were strong allelic differences in pollen. One allele underexpressed pollen ADH1 at 48% of the wild-type level, and another overexpressed pollen ADH1 at 163% of the wild-type level. Quantitative RNase protection assays demonstrated that the mutant phenotypes reflected changes in the levels of steady state mRNA in pollen. These data provide a definitive demonstration of an overexpression mutant in plants and further show that marked increases in mRNA levels can follow minor alterations in central untranslated leader sequences. The nucleotide sequence of 12 new revertant alleles and the molecular mechanisms responsible for pollen-specific gene expression are discussed.     

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.     

The Mutation Bronze-Mutable 4 Derivative 6856 in Maize Is Caused by the Insertion of a Novel 6.7-Kilobase Pair Transposon in the Untranslated Leader Region of the Bronze-1 Gene

The Ds-controlled allele, bz-m4 Derivative 6856 [bz-m4 D6856], is reported to have an altered temporal- and tissue-specific pattern of gene expression. We have cloned this allele and have characterized it at the molecular level. The mutation was caused by the insertion of a complex transposon-like structure 36 base pairs downstream from the Bz mRNA cap site. The insert is 6.7-kbp long. Ds elements, each approximately 2 kbp in length, are at both ends of the insert. The sequence between the Ds elements is a partial duplication of flanking sequences from the 3' end of the Bz gene. These data suggest that Ds initially inserted near the 3' end of the gene and mobilized adjacent sequences as it transposed.     

Tam3 produces a suppressible allele of the DAG locus of Antirrhinum majus similar to Mu-suppressible alleles of maize

Tam3 from Antirrhinum majus belongs to the Ac/Ds family of transposable elements. An allele of the DAG locus of Antirrhinum ( dag ::Tam3), which is required for chloroplast development and leaf palisade differentiation, has been generated by Tam3 insertion into the untranslated leader sequence of the gene. This allele gives rise to a cold-sensitive phenotype, where mutant tissue containing wild-type revertant somatic sectors is observed in the leaves of plants grown at 15°C, while leaves of plants grown at 25°C appear near wild-type. The temperature sensitivity of dag ::Tam3 results from expression of the DAG locus responding to the activity of the transposable element, the transposition of which is very sensitive to growing temperature. Genetic suppression of Tam3 transposition, using the STABILISER locus, also results in suppression of the dag mutant phenotype. dag ::Tam3 represents a Tam3-suppressible allele similar to those described for Mu transposons in maize. Suppression of the dag mutant phenotype in response to element inactivation appears to result from use of an alternative promoter at the 3' end of the Tam3 element. The production of suppressible alleles by an Ac-like element is discussed in relation to the mutagenic potential of plant transposons in producing complex genetic diversity.     

Excision of a transposable element from a viral vector introduced into maize plants by agroinfection

The geminivirus maize streak virus (MSV) was used as a vector to introduce the maize transposable element Dissociation (Ds) and to study its excision in maize plants. MSV carrying Ds1 in its genome was introduced into maize plants by agroinfection. Excision of the Ds1 element from the MSV genome was detected only when functions from the transposable element Activator (Ac) were supplied in trans, either endogenously by the recipient maize plant or by co-transformation with Agrobacterium carrying a genomic Ac clone. The excision of Ds1 could easily be visualized by the appearance of viral symptoms induced by the revertant virus. The junction sequences left on the MSV genome after excision revealed 'footprints' typical of transposition as described for maize. From these results, we conclude that transposition functions in our system and that the use of the MSV replicon provides a rapid and simple tool for the investigation of the excision of transposable elements in maize plants.