A carnation anthocyanin mutant is complemented by the glutathione S-transferases encoded by maize Bz2 and petunia An9.

Particle bombardment was used to elucidate the function of Flavonoid3, a late-acting anthocyanin gene of the ornamental plant, carnation ( Dianthus caryophyllus L.). The fl3 mutation conditions dilute anthocyanin coloration that closely resembles phenotypes produced by the anthocyanin mutants bz2 of maize and an9 of petunia. Bz2 and An9 encode glutathione S-transferases (GSTs) involved in vacuolar sequestration of anthocyanins. Constructs containing either of these or another late-function maize gene, Bronze1 (UDPglucose:flavonol 3- O-glucosyltransferase), were introduced via microprojectile bombardment into fl3 petals. Complementation resulted only from Bz2 and An9, indicating that Fl3 encodes a GST involved in the transport of anthocyanins to the vacuole. The observed result in carnation, an angiosperm phylogenetically distant from maize and petunia, indicates that GST activity might be a universal step in the anthocyanin pathway. Microprojectile bombardment was used to identify late-pathway anthocyanin mutations, which may be responsible for the pale anthocyanin coloration of important cultivars in many species but which can be difficult to characterize by other means.

Imprinting of R-r, paramutation of B-I and Pl, and epigenetic silencing of MuDR/Mu transposons in Zea mays L. are coordinately affected by inbred background.

The extent of imprinting at R-r, frequency of paramutation at B-Intense and Pl, and epigenetic silencing of Mu transposons were evaluated in the W23 and A188 inbred lines of maize. All types of epigenetic phenomena affecting these loci of the anthocyanin pathway occurred more frequently in the W23 inbred line. Absence of down-regulation was dominant in F1 hybrid progeny. Identical alleles programme lower anthocyanin accumulation in A188 than in W23, and A188 plants develop more rapidly than W23. The possibilities that specific genetic factors, intrinsic gene expression levels and/or the rapidity of the life cycle modulate epigenetic gene controls are discussed.

Somatic and germinal mobility of the RescueMu transposon in transgenic maize.

RescueMu, a Mu1 element containing a bacterial plasmid, is mobilized by MuDR in transgenic maize. Somatic excision from a cell-autonomous marker gene yields >90% single cell sectors; empty donor sites often have deletions and insertions, including up to 210 bp of RescueMu/Mu1 terminal DNA. Late somatic insertions are contemporaneous with excisions, suggesting that "cut-and-paste" transposition occurs in the soma. During reproduction, RescueMu transposes infrequently from the initial transgene array, but once transposed, RescueMu is suitable for high throughput gene mutation and cloning. As with MuDR/Mu elements, heritable RescueMu insertions are not associated with excisions. Both somatic and germinal RescueMu insertions occur preferentially into genes and gene-like sequences, but they exhibit weak target site preferences. New insights into Mu behaviors are discussed with reference to two models proposed to explain the alternative outcomes of somatic and germinal events: a switch from somatic cut-and-paste to germinal replicative transposition or to host-mediated gap repair from sister chromatids.

A maize MuDR transposon promoter shows limited autoregulation.

Transgenic maize expressing luciferase under the control of the mudrB terminal inverted repeat promoter (TIRB) of the MuDR transposon was assayed for transgene expression in active and inactive Mutator lines. We find that active MuDR elements increase TIRB-luciferase expression by 2- to 10-fold, relative to nonMuDR or silenced MuDR lines, in embryonic leaves in 75% of plants tested. However, this increase does not persist in juvenile and adult leaves. In pollen, TIRB-luciferase expression is up to 100-fold higher than in leaves but is unaffected by the presence or absence of active MuDR. Because the MuRA transposase binds to a motif within TIRB, we hypothesize that MURA may act as a weak transcriptional activator of TIRB or may partly inhibit host-induced silencing of TIRB in active Mutator lines during the early stages of somatic growth. Our results contrast with those for the maize transposon Spm, in which the TNPA transposase acts as a repressor of the Spm promoter in active Spm lines.

Computational methods for gene annotation: the Arabidopsis genome.

Since the structure of the DNA molecule was identified half a century ago, the complete genome sequence has been determined for 37 prokaryotes and several eukaryotes. With the exponential growth of genetic information, bioinformatics has attempted to predict gene locations and functions in cyberspace prior to experimental confirmation at the bench.

Expression and post-transcriptional regulation of maize transposable element MuDR and its derivatives.

The transposition of Mu elements underlying Mutator activity in maize requires a transcriptionally active MuDR element. Despite variation in MuDR copy number and RNA levels in Mutator lines, transposition events are consistently late in plant development, and Mu excision frequencies are similar. Here, we report previously unsuspected and ubiquitous MuDR homologs that produce both RNA and protein. MuDR transcript levels are proportional to MuDR copy number, and homolog transcript levels increase in active Mutator lines. A subset of homologs exhibits constitutive transcription in MuDR(-) and epigenetically silenced MuDR lines, suggesting independent transcriptional regulation. Surprisingly, immunodetection demonstrated nearly invariant levels of MuDR and homolog protein products in all tested Mutator and non-Mutator stocks. These results suggest a strict control over protein production, which might explain the uniform excision frequency of Mu elements. Moreover, the nonfunctional proteins encoded by homologs may negatively regulate Mutator activity and represent part of the host defense against this transposon family.

The MuDR transposon terminal inverted repeat contains a complex plant promoter directing distinct somatic and germinal programs.

The Mu transposons of maize are under stringent developmental control. Elements excise at high frequencies in terminally dividing somatic cells, but not in meristems. Mu elements in germinal cells amplify, without excision, and insert throughout the genome. All activities require MuDR, which encodes two genes, mudrA and mudrB, whose near-identical promoters are located in the transposon terminal inverted repeats (TIR). We have fused the 216 bp TIR of the mudrB gene to GUS and luciferase reporters. We demonstrate that TIRB programs reporter expression in diverse, meristematic somatic cells, paradoxically in those cells in which Mu excisions are repressed. In germinal cells, immature tassel and mature pollen, reporter expression increases up to 20-fold compared to leaf. By RNA blot hybridization, we demonstrate that endogenous mudrB and mudrA transcripts increase significantly in mature pollen; sequence comparisons demonstrate that the MuDR TIRs contain plant cell-cycle enhancer motifs and functionally defined pollen enhancers. Therefore, the MuDR TIR promoters are developmentally regulated in both somatic and germinal tissues. Because database sequence analysis suggests that the MuDR TIR enhancers should be functional in both monocots and dicots, we suggest that the native MuDR promoter be used in attempts to transfer the unique behavior of Mu transposition to heterologous hosts.

AN9, a petunia glutathione S-transferase required for anthocyanin sequestration, is a flavonoid-binding protein.

AN9 is a glutathione S-transferase from petunia (Petunia hybrida) required for efficient anthocyanin export from the site of synthesis in the cytoplasm into permanent storage in the vacuole. For many xenobiotics it is well established that a covalent glutathione (GSH) tag mediates recognition of molecules destined for vacuolar sequestration by a tonoplast-localized ATP-binding cassette pump. Here we inquired whether AN9 catalyzes the formation of GSH conjugates with flavonoid substrates. Using high-performance liquid chromatography analysis of reaction mixtures containing enzyme, GSH, and flavonoids, including anthocyanins, we could detect neither conjugates nor a decrease in the free thiol concentration. These results suggest that no conjugate is formed in vitro. However, AN9 was shown to bind flavonoids using three assays: inhibition of the glutathione S-transferase activity of AN9 toward the common substrate 1-chloro 2,4-dinitrobenzene, equilibrium dialysis, and tryptophan quenching. We conclude that AN9 is a flavonoid-binding protein, and propose that in vivo it serves as a cytoplasmic flavonoid carrier protein.

Plant glutathione S-transferases: enzymes with multiple functions in sickness and in health.

Glutathione S-transferases (GSTs) are abundant proteins encoded by a highly divergent, ancient gene family. Soluble GSTs form dimers, each subunit of which contains active sites that bind glutathione and hydrophobic ligands. Plant GSTs attach glutathione to electrophilic xenobiotics, which tags them for vacuolar sequestration. The role of GSTs in metabolism is unclear, although their complex regulation by environmental stimuli implies that they have important protective functions. Recent studies show that GSTs catalyse glutathione-depend-ent isomerizations and the reduction of toxic organic hydroperoxides. GSTs might also have non-catalytic roles as carriers for phytochemicals.

Saturation mutagenesis using maize transposons.

Transposon mutagenesis facilitates gene discovery by tagging genes for cloning. New genomics projects are now cataloging transposon insertion sites to define all maize genes. Once identified, transposon insertions are 'hot spots' for generating new alleles that are useful in functional studies.

The late developmental pattern of Mu transposon excision is conferred by a cauliflower mosaic virus 35S -driven MURA cDNA in transgenic maize.

The MuDR element responsible for Mutator activities in maize encodes two genes, mudrA and mudrB. Each encodes multiple transcripts hypothesized to regulate, directly or indirectly, the unique late timing and switch in transposition mechanism during maize development. mudrA, which encodes the MURA transposase, is unstable in bacterial plasmids, a technical problem solved by using phage M13 as a vector to prepare DNA for biolistic transformation. In transgenic maize, a single 2.7-kb mudrA cDNA predicted to encode an 823-amino acid protein is sufficient to catalyze late somatic excisions, despite removal of the native promoter, alternative transcription start sites, known introns, polymorphic 5' and 3' untranslated sequences, and the mudrB gene. These results suggest that post-translational regulation confers Mu excision timing. The transgene is active in lines containing silencing MuDR elements. This suggests that endogenous MuDR transposons do not measurably immunize the host against expression of a homologous transgene.

Gene discovery using the maize genome database ZmDB.

Zea mays DataBase (ZmDB) is a repository and analysis tool for sequence, expression and phenotype data of the major crop plant maize. The data accessible in ZmDB are mostly generated in a large collaborative project of maize gene discovery, sequencing and phenotypic analysis using a transposon tagging strategy and expressed sequence tag (EST) sequencing. ESTs constitute most of the current content. Database search tools, convenient links to external databases, and novel sequence analysis programs for spliced alignment are provided and together serve as an efficient protocol for gene discovery by sequence inspection. ZmDB can be accessed at http://zmdb. iastate.edu. ZmDB also provides web-based ordering of materials generated in the project, including EST and genomic DNA clones, seeds of mutant plants and microarrays of amplified EST and genomic DNA sequences.

Test of the combinatorial model of intron recognition in a native maize gene.

Previous studies have established that splice site selection and splicing efficiency in plants depend strongly on local compositional contrast consisting of high exon G+C content relative to high intron U content. The combinatorial model of plant intron recognition posits that splice site sequences as well as local intron and exon sequences contribute to splice site selection and splicing efficiency. Most of the previous studies used synthetic or chimeric constructs, often tested in heterologous hosts. To perform a more critical test of the combinatorial model in a native context, the single intron of the maize Bronze2 gene and its flanking exons were modified by site-directed mutagenesis. Splicing efficiency was tested in maize protoplasts. Results show that a higher U content in the flanking 5' exon, whether close to or distant from the 5' splice site, did not modify splicing efficiency. Decreasing exon G+C content dramatically impaired splicing. Increasing intron G+C content or decreasing intron U content adversely impacted splicing. In all constructs splicing occurred exclusively at the original 5' and 3' splice sites. These results are consistent with the hypothesis that exon G+C content and intron U content contribute separate but complementary aspects of intron definition in the native Bz2 transcript.

Functional complementation of anthocyanin sequestration in the vacuole by widely divergent glutathione S-transferases.

Glutathione S-transferases (GSTs) traditionally have been studied in plants and other organisms for their ability to detoxify chemically diverse herbicides and other toxic organic compounds. Anthocyanins are among the few endogenous substrates of plant GSTs that have been identified. The Bronze2 (Bz2) gene encodes a type III GST and performs the last genetically defined step of the maize anthocyanin pigment pathway. This step is the conjugation of glutathione to cyanidin 3-glucoside (C3G). Glutathionated C3G is transported to the vacuole via a tonoplast Mg-ATP-requiring glutathione pump (GS-X pump). Genetically, the comparable step in the petunia anthocyanin pathway is controlled by the Anthocyanin9 (An9) gene. An9 was cloned by transposon tagging and found to encode a type I plant GST. Bz2 and An9 have evolved independently from distinct types of GSTs, but each is regulated by the conserved transcriptional activators of the anthocyanin pathway. Here, a phylogenetic analysis is presented, with special consideration given to the origin of these genes and their relaxed substrate requirements. In particle bombardment tests, An9 and Bz2 functionally complement both mutants. Among several other GSTs tested, only soybean GmGST26A (previously called GmHsp26A and GH2/4) and maize GSTIII were found to confer vacuolar sequestration of anthocyanin. Previously, these genes had not been associated with the anthocyanin pathway. Requirements for An9 and Bz2 gene function were investigated by sequencing functional and nonfunctional germinal revertants of an9-T3529, bz2::Ds, and bz2::Mu1.

Transcriptionally active MuDR, the regulatory element of the mutator transposable element family of Zea mays, is present in some accessions of the Mexican land race Zapalote chico.

To date, mobile Mu transposons and their autonomous regulator MuDR have been found only in the two known Mutator lines of maize and their immediate descendants. To gain insight into the origin, organization, and regulation of Mutator elements, we surveyed exotic maize and related species for cross-hybridization to MuDR. Some accessions of the mexican land race Zapalote chico contain one to several copies of full-length, unmethylated, and transcriptionally active MuDR-like elements plus non-autonomous Mu elements. The sequenced 5.0-kb MuDR-Zc element is 94.6% identical to MuDR, with only 20 amino acid changes in the 93-kD predicted protein encoded by mudrA and ten amino acid changes in the 23-kD predicted protein of mudrB. The terminal inverted repeat (TIR) A of MuDR-Zc is identical to standard MuDR; TIRB is 11.2% divergent from TIRA. In Zapalote chico, mudrA transcripts are very rare, while mudrB transcripts are as abundant as in Mutator lines with a few copies of MuDR. Zapalote chico lines with MuDR-like elements can trans-activate reporter alleles in inactive Mutator backgrounds; they match the characteristic increased forward mutation frequency of standard Mutator lines, but only after outcrossing to another line. Zapalote chico accessions that lack MuDR-like elements and the single copy MuDR a1-mum2 line produce few mutations. New mutants recovered from Zapalote chico are somatically stable.