Visual detection of transposition of the maize element activator (ac) in tobacco seedlings

A bacterial streptomycin resistance gene (SPT) was engineered to make it possible to detect visually the transposition of the maize transposon Activator (Ac) in tobacco. In the presence of streptomycin, transgenic seedlings carrying the SPT gene appear green, whereas those carrying an SPT:: Ac construct display clones of green cells on a white background. Fully green seedlings arise in the progeny of SPT:: Ac transformants as a result of excision of Ac before fertilization. About half of these germinal revertants carry a transposed Ac element. Therefore, SPT:: Ac constitutes an efficient marker for selecting plants that have undergone transposition. In maize, there is a negative effect of increasing Ac dosage on the frequency and timing of Ac transposition. This negative effect is not observed in tobacco with the streptomycin variegation assay.

Controlling element-induced alterations in UDPglucose:flavonoid glucosyltransferase, the enzyme specified by the bronze locus in maize

The bz locus in maize, which directs synthesis of the enzyme UDPglucose:flavonoid glucosyltransferase (UFGT) in the endosperm, is one of many loci at which controlling element-induced phenotypic changes are known. To characterize the nature of such modifications, several bz mutants derived by transposition of the controlling element Ds to the Bz gene were analyzed. Three mutants were found to lack UFGT at all stages of endosperm development. Two others appeared to make an altered UFGT, and in one of these the enzyme showed an altered developmental profile.

Heterogeneous flavonoid glucosyltransferases in purple derivatives from a controlling element-suppressed bronze mutant in maize

The Ds(Dissociation)-suppressed bronze mutant bz-m2(DI), which is extremely stable in the absence of the regulatory element Ac (Activator), becomes both somatically and germinally unstable when Ac is present. Instability in the germ line may result in the generation of stable (Ac-nonresponding), colored Bz' derivatives. The characterization of several properties of the Bz-controlled enzyme UDPglucose: flavonoid 3-O-glucosyltransferase from mature kernel endosperms of 15 such Bz' derivatives has revealed two distinct groups. The enzyme in group I Bz' derivatives does not differ from the normal enzyme in the Bz progenitor allele of bz-m2(DI). Group II Bz' derivatives, on the other hand, make altered, labile UDPglucose:flavonoid glucosytransferases different from the normal enzyme and probably different from each other. The significance of these two classes of derivatives and possible mechanisms involved in their origin are discussed.

Identification of an R-locus region that controls the tissue specificity of anthocyanin formation in maize

The R locus in maize controls the tissue specificity of anthocyanin formation. Recombination between two different R-locus alleles with unique pigmentation domains has resulted in the generation of a nonparental allelic type that displays a third kind of tissue specificity. These novel changes in tissue specificity occurred in very low frequency (1 x 10(-5)). In light of this finding and of recent results concerning the regulation by R of the enzyme UDPG: flavonoid 3-0-glucosyltransferase, specified by the B(z) locus, a model dealing with the genetic control of tissue-specific functions in multicellular organisms is proposed.

The highly recombinogenic bz locus lies in an unusually gene-rich region of the maize genome

The bronze (bz) locus exhibits the highest rate of recombination of any gene in higher plants. To investigate the possible basis of this high rate of recombination, we have analyzed the physical organization of the region around the bz locus. Two adjacent bacterial artificial chromosome clones, comprising a 240-kb contig centered around the Bz-McC allele, were isolated, and 60 kb of contiguous DNA spanning the two bacterial artificial chromosome clones was sequenced. We find that the bz locus lies in an unusually gene-rich region of the maize genome. Ten genes, at least eight of which are shown to be transcribed, are contained in a 32-kb stretch of DNA that is uninterrupted by retrotransposons. We have isolated nearly full length cDNAs corresponding to the five proximal genes in the cluster. The average intertranscript distance between them is just 1 kb, revealing a surprisingly compact packaging of adjacent genes in this part of the genome. At least 11 small insertions, including several previously described miniature inverted repeat transposable elements, were detected in the introns and 3' untranslated regions of genes and between genes. The gene-rich region is flanked at the proximal and distal ends by retrotransposon blocks. Thus, the maize genome appears to have scattered regions of high gene density similar to those found in other plants. The unusually high rate of intragenic recombination seen in bz may be related to the very high gene density of the region.

A maize sesquiterpene cyclase gene induced by insect herbivory and volicitin: characterization of wild-type and mutant alleles

Plants can defend themselves from herbivorous insects by emitting volatile chemical signals that attract natural enemies of the herbivore. For example, maize seedlings attacked by beet armyworm larvae (Spodoptera exigua) produce a mixture of terpenoid and indole volatiles that serve to attract parasitic wasps. A key step in terpenoid biosynthesis is the conversion of acyclic prenyl diphosphates to terpenoid compounds by specific terpenoid synthases (cyclases). We have cloned a maize sesquiterpene cyclase gene, stc1, by transposon tagging and have identified two deletion mutations of the gene. The stc1 gene is located on chromosome 9S and does not seem to have a closely related ortholog in the maize genome. It is induced 15- to 30-fold in maize leaves by beet armyworm larvae feeding or by application of purified volicitin, the insect-derived elicitor, at a mechanically wounded site. stc1 induction is systemic, because undamaged leaves of the same plant show a similar increase in stc1 transcription. Analysis of volatiles from volicitin-treated seedlings revealed that a major naphthalene-based sesquiterpene was present in wild-type seedlings but absent in the Ac-insertion and x-ray-deletion mutants. Therefore, we have identified a maize gene that responds to caterpillar herbivory by producing a chemical defense signal that most likely serves to attract natural enemies of the herbivore.

A gene-enriched BAC library for cloning large allele-specific fragments from maize: isolation of a 240-kb contig of the bronze region

A generic bacterial artificial chromosome (BAC) library from a complex plant genome like maize may not be suitable for some types of genomic analysis, for example, for establishing correlations between the genetic and the physical organization of a given chromosome region. Previously, we carried out extensive genetic analysis of the bronze (Bz) region in Zea mays using a W22 inbred line carrying the Bz-McC allele; however, BAC libraries of that line are neither available nor under construction. Here, we report the isolation of large, adjacent BAC clones of this region from a partial BAC library of W22. We developed a BAC vector suitable for cloning NotI fragments and used it to clone size-fractionated genomic DNA that had been cut to completion with the methylation-sensitive, rare-cutting enzyme NotI. This strategy resulted in a very significant enrichment of large genic DNA. From a library of about 20,000 BACs, containing just two-thirds of a maize genome, we isolated 16 BAC clones of the 110-kb distal Bz fragment and 10 BAC clones of the 130-kb proximal Bz fragment. This recovery means that our strategy resulted in a 15- to 24-fold enrichment of specific sequences. The order of the BAC clones in the 240-kb contig, predetermined from an internal NotI site in the Bz-McC allele was confirmed by hybridization with sequences from sites previously mapped proximal and distal to Bz and by sequencing. To show the general utility of our approach and the value of our partial BAC library, we also isolated BAC clones of other sequences, such as tub4 and the complex R-r allele, contained in the same size fraction of DNA. This is the first report of the use of a BAC vector to clone allele-specific large DNA fragments from a plant with a large genome, circumventing the need to construct a complete BAC library.

Resistance to turnip crinkle virus in Arabidopsis is regulated by two host genes and is salicylic acid dependent but NPR1, ethylene, and jasmonate independent

Inoculation of turnip crinkle virus (TCV) on the resistant Arabidopsis ecotype Dijon (Di-17) results in the development of a hypersensitive response (HR) on the inoculated leaves. To assess the role of the recently cloned HRT gene in conferring resistance, we monitored both HR and resistance (lack of viral spread to systemic tissues) in the progeny of a cross between resistant Di-17 and susceptible Columbia plants. As expected, HR development segregated as a dominant trait that corresponded with the presence of HRT. However, all of the F(1) plants and three-fourths of HR(+) F(2) plants were susceptible to the virus. These results suggest the presence of a second gene, termed RRT, that regulates resistance to TCV. The allele present in Di-17 appears to be recessive to the allele or alleles present in TCV-susceptible ecotypes. We also demonstrate that HR formation and TCV resistance are dependent on salicylic acid but not on ethylene or jasmonic acid. Furthermore, these phenomena are unaffected by mutations in NPR1. Thus, TCV resistance requires a yet undefined salicylic acid-dependent, NPR1-independent signaling pathway.

Characterization of a new Arabidopsis mutant exhibiting enhanced disease resistance

In many plant-pathogen interactions, resistance is associated with the synthesis and accumulation of salicylic acid (SA) and pathogenesis-related (PR) proteins. At least two general classes of mutants with altered resistance to pathogen attack have been identified in Arabidopsis. One class exhibits increased susceptibility to pathogen infection; the other class exhibits enhanced resistance to pathogens. In an attempt to identify mutations in resistance-associated loci, we screened a population of T-DNA tagged Arabidopsis thaliana ecotype Wassilewskija (Ws) for mutants showing constitutive expression of the PR-1 gene (cep). A mutant was isolated and shown to constitutively express PR-1, PR-2, and PR-5 genes. This constitutive phenotype segregated as a single recessive trait in the Ws genetic background. The mutant also had elevated levels of SA, which are responsible for the cep phenotype. The cep mutant spontaneously formed hypersensitive response (HR)-like lesions on the leaves and cotyledons and also exhibited enhanced resistance to virulent bacterial and fungal pathogens. Genetic analyses of segregating progeny from outcrosses to other ecotypes unexpectedly revealed that alterations in more than one gene condition the constitutive expression of PR genes in the original mutant. One of the mutations, designated cpr20, maps to the lower arm of chromosome 4 and is required for the cep phenotype. Another mutation, which has been termed cpr21, maps to chromosome 1 and is often, but not always, associated with this phenotype. The recessive nature of the cep trait suggests that the CPR20 and CPR21 proteins may act as negative regulators in the disease resistance signal transduction pathway.

Origination of Ds elements from Ac elements in maize: evidence for rare repair synthesis at the site of Ac excision

Although it has been known for some time that the maize transposon Ac can mutate to Ds by undergoing internal deletions, the mechanism by which these mutations arise has remained conjectural. To gain further insight into this mechanism in maize we have studied a series of Ds elements that originated de novo from Ac elements at known locations in the genome. We present evidence that new, internally deleted Ds elements can arise at the Ac donor site when Ac transposes to another site in the genome. However, internal deletions are rare relative to Ac excision footprints, the predominant products of Ac transposition. We have characterized the deletion junctions in five new Ds elements. Short direct repeats of variable length occur adjacent to the deletion junction in three of the five Ds derivatives. In the remaining two, extra sequences or filler DNA is inserted at the junction. The filler DNAs are identical to sequences found close to the junction in the Ac DNA, where they are flanked by the same sequences that flank the filler DNA in the deletion. These findings are explained most simply by a mechanism involving error-prone DNA replication as an occasional alternative to end-joining in the repair of Ac-generated double-strand breaks.

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.

Recombination occurs uniformly within the bronze gene, a meiotic recombination hotspot in the maize genome

The bronze (bz) gene is a recombinational hotspot in the maize genome: its level of meiotic recombination per unit of physical length is > 100-fold higher than the genome's average and is the highest of any plant gene analyzed to date. Here, we examine whether recombination is also unevenly distributed within the bz gene. In yeast genes, recombination (conversion) is polarized, being higher at the end of the gene where recombination is presumably initiated. We have analyzed products of meiotic recombination between heteroallelic pairs of bz mutations in both the presence and absence of heterologies and have sequenced the recombination junction in 130 such Bz intragenic recombinants. We have found that in the absence of heterologies, recombination is proportional to physical distance across the bz gene. The simplest interpretation for this lack of polarity is that recombination is initiated randomly within the gene. Insertion mutations affect the frequency and distribution of intragenic recombination events at bz, creating hotspots and coldspots. Single base pair heterologies also affect recombination, with fewer recombination events than expected by chance occurring in regions of the bz gene with a high density of heterologies. We also provide evidence that meiotic recombination in maize is conservative, that is, it does not introduce changes, and that meiotic conversion tracts are continuous and similar in size to those in yeast.

Sesqui-Ds, the chromosome-breaking insertion at bz-m1, links double Ds to the original Ds element

The bz-m1 mutation in maize was one of the first to arise by direct transposition of the chromosome-breaking Ds element from its original or 'standard' location in chromosome 9S to a known locus in the same chromosome arm. Thus, elucidation of its structure should shed light on the nature of the original Ds element described by McClintock in 1948. The Ds insertion in bz-m1 has been reported to be only 1.2 kb long-much shorter than other chromosome-breaking Ds elements that have been described. We have characterized here the Ds element in our bz-m1 stocks and have confirmed by genetic and molecular tests that, in the presence of Ac, it acts as a chromosome breaker. The Ds insertion at bz-m1 is 1260 bp long. Besides its normal 5' and 3' ends, it contains an internal 3' end at the same junction as the chromosome-breaking double Ds element that has been found in several sh mutations. Thus, it appears to have arisen from the 4.1-kb double Ds by internal deletion of 2.9 kb. Because the element has lost one internal 5' end, but retains the chromosome-breaking properties of double Ds, we have named it sesqui-Ds (sDs). The origin, structure and properties of sDs vis-à-vis double Ds support the hypothesis that double Ds corresponds to the chromosome-breaking Ds element at the 'standard' location in 9S.

Directed tagging of the Arabidopsis FATTY ACID ELONGATION1 (FAE1) gene with the maize transposon activator

The FATTY ACID ELONGATION1 (FAE1) gene of Arabidopsis is required for the synthesis of very long chain fatty acids in the seed. The product of the FAE1 gene is presumed to be a condensing enzyme that extends the chain length of fatty acids from C18 to C20 and C22. We report here the cloning of FAE1 by directed transposon tagging with the maize element Activator (Ac). An unstable fae1 mutant was isolated in a line carrying Ac linked to the FAE1 locus on chromosome 4. Cosegregation and reversion analyses established that the new mutant was tagged by Ac. A DNA fragment flanking Ac was cloned by inverse polymerase chain reaction and used to isolate FAE1 genomic clones and a cDNA clone from a library made from immature siliques. The predicted amino acid sequence of the FAE1 protein shares homology with those of other condensing enzymes (chalcone synthase, stilbene synthases, and beta-ketoacyl-acyl carrier protein synthase III), supporting the notion that FAE1 is the structural gene for a synthase or condensing enzyme. FAE1 is expressed in developing seed, but not in leaves, as expected from the effect of the fae1 mutation on the fatty acid compositions of those tissues.

A Mutant of Arabidopsis Deficient in the Elongation of Palmitic Acid

The overall fatty acid composition of leaf lipids in a mutant of Arabidopsis thaliana was characterized by an increased level of 16:0 and a concomitant decrease of 18-carbon fatty acids as a consequence of a single recessive nuclear mutation at the fab1 locus. Quantitative analysis of the fatty acid composition of individual lipids established that lipids synthesized by both the prokaryotic and eukaryotic pathways were affected by the mutation. Direct enzyme assays demonstrated that the mutant plants were deficient in the activity of 3-ketoacyl-acyl carrier protein synthase II; therefore, it is inferred that fab1 may encode this enzyme. Labeling experiments with [14C]acetate and lipase positional analysis indicated that the mutation results in a small shift in the partitioning of lipid synthesis between the prokaryotic and eukaryotic pathways. Synthesis of chloroplast lipids by the prokaryotic pathway was increased with a corresponding reduction in the eukaryotic pathway.

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.

Preferential transposition ofAc to linked sites in Arabidopsis

We have investigated the pattern of transposition of an intact, 4.6-kbAc element inArabidopsis thaliana. Because the trans-acting transposition function (transposase) ofAc is not fully penetrant in Arabidopsis, it is not possible to use it as a diagnostic feature to scoreAc genetically, as has been done in maize and tobacco. Instead, the presence or absence of a transposedAc (trAc) was monitored by Southern blots. Germinal transpositions from the marker SPT::Ac were selected using a streptomycin germination assay and scored for the presence of atrAc. Segregation of thetrAc element and the SPT donor locus was scored in the F2 progeny of the germinal revertants, and the recombination fraction between thetrAc element and SPT was estimated by the method of maximum likelihood. We have found that, as in maize and tobacco, receptor sites fortrAcs in Arabidopsis tend to be linked to theAc donor locus.

Tagging and Cloning of a Petunia Flower Color Gene with the Maize Transposable Element Activator

We report here the use of the maize transposable element Activator (Ac) to isolate a dicot gene. Ac was introduced into petunia, where it transposed into Ph6, one of several genes that modify anthocyanin pigmentation in flowers by affecting the pH of the corolla. Like other Ac-mutable alleles, the new mutation is unstable and reverts to a functional form in somatic and germinal tissues. The mutant gene was cloned using Ac as a probe, demonstrating the feasibility of heterologous transposon tagging in higher plants. Confirmation that the cloned DNA fragment corresponded to the mutated gene was obtained from an analysis of revertants. In every case examined, reversion to the wild-type phenotype was correlated with restoration of a wild-type-sized DNA fragment. New transposed Acs were detected in many of the revertants. As in maize, the frequency of somatic and germinal excision of Ac from the mutable allele appears to be dependent on genetic background.

Effects of gene dosage and sequence modification on the frequency and timing of transposition of the maize element Activator (Ac) in tobacco

The effect of Ac copy number on the frequency and timing of germinal transposition in tobacco was investigated using the streptomycin phosphotransferase gene (SPT) as an excision marker. The activity of one and two copies of the element was compared by selecting heterozygous and homozygous progeny of transformants carrying single SPT::Ac inserts. It was observed that increasing gene copy not only increases the transposition frequency, but also occasionally alters the timing of transposition such that earlier events are obtained. The result is that some homozygous plants generate multiple streptomycin resistant progeny carrying the same transposed Ac (trAc) element. We have also investigated the effect of modification of the sequence in the region around 82 bp downstream of the polyadenylation site and 177 bp from the 3' end of the element on germinal excision frequencies. Alteration of three bases to create a Bgl II site at this location caused a minor decrease in germinal excision events, but insertion of four bases to create a Cla I site caused a 10-fold decrease in the transposition activity of the Ac element.

Germinal and somatic activity of the maize element Activator (Ac) in Arabidopsis

We have investigated the germinal and somatic activity of the maize Activator (Ac) element in Arabidopsis with the objective of developing an efficient transposon-based system for gene isolation in that plant. Transposition activity was assayed with a chimeric marker that consists of the cauliflower mosaic virus 35S promoter and a bacterial streptomycin phosphotransferase gene (SPT). Somatic activity was detected in seedlings germinated on plates containing streptomycin as green-resistant sectors against a background of white-sensitive cells. Germinal excisions resulted in fully green seedlings. The transposition frequency was extremely low when a single copy of the transposon was present, but appeared to increase with an increase in Ac copy number. Plants that were selected as variegated produced an increased number of green progeny. The methylation state of the Ac elements in lines with either low or high levels of excision was assessed by restriction analysis. No difference was found between these lines, indicating that the degree of methylation did not contribute to the level of Ac activity. Germinal excision events were analyzed molecularly and shown to carry reinserted transposons in about 50% of the cases. In several instances, streptomycin-resistant siblings carried the same transposed Ac element, indicating that excision had occurred prior to meiosis in the parent. We discuss parameters that need to be considered to optimize the use of Ac as a transposon tag in Arabidopsis.

Chromosome breakage by pairs of closely linked transposable elements of the Ac-Ds family in maize

Chromosome breaks and hence chromosomal rearrangements often occur in maize stocks harboring transposable elements (TEs), yet it is not clear what types of TE structures promote breakage. We have shown previously that chromosomes containing a complex transposon structure consisting of an Ac (Activator) element closely linked in direct orientation to a terminally deleted or fractured Ac (fAc) element have a strong tendency to break during endosperm development. Here we show that pairs of closely linked transposons with intact ends, either two Ac elements--a common product of Ac transposition--or an Ac and a Ds (Dissociation) element, can constitute chromosome-breaking structures, and that the frequency of breakage is inversely related to intertransposon distance. Similar structures may also be implicated in chromosome breaks in other eukaryotic TE systems known to produce chromosomal rearrangements. The present findings are discussed in light of a model of chromosome breakage that is based on the transposition of a partially replicated macrotransposon delimited by the outside ends of the two linked TEs.

Novel seed lipid phenotypes in combinations of mutants altered in fatty acid biosynthesis inArabidopsis

The seed fatty acid (FA) composition of various single mutant combinations ofArabidopsis thaliana that affect FA biosynthesis has been examined. Double mutant combinations offae, a mutation affecting CIS elongation, and a series of four other FA biosynthetic mutants were synthesized. The four other single mutants were:fad2 andfad3, which are deficient in 18∶1 and 18∶2 desaturation, respectively;fab1, which is elevated in 16∶0 and decreased in 18∶1; andfab2, which is elevated in 18∶0 and decreased in 18∶1. The superimposition of two blocks in the FA biosynthetic pathway leads to dramatic changes in the FA content of the double mutants. The tenArabidopsis stocks analyzed to date (wild-type, five single mutants, and four double mutants) make seed oils with a wide range of FA compositions, and illustrate the diversity of oils it is possible to obtain from a single plant species.

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.

Isolation of EMS-induced mutants in Arabidopsis altered in seed fatty acid composition

Mutants of Arabidopsis thaliana were identified by screening pedigreed M3 seed collections from EMS-treated plants for changes in fatty acid (FA) composition. The FA phenotypes of the most dramatic mutants are as follows: G30 and 1E5 (allelic) lack linolenic acid (18∶3) and are elevated in linoleic acid (18∶2); 4A5 is deficient in 18∶2 and 18∶3 and fourfold increased in oleic acid (18∶1); 9A1 lacks all FAs > C18 and is twofold increased in 18∶1; 1A9 is twofold increased in palmitic acid (16∶0) and decreased by one-half in 18∶1; 2A11 is two-to threefold increased in stearic acid (18∶0) and decreased by one-half in 18∶1. Based on segregation of F2 selfed plants derived from crosses to wild type, all of these phenotypes are the result of single gene mutations.

Preferential transposition of the maize element Activator to linked chromosomal locations in tobacco

The autonomous maize transposon Activator (Ac) has been used in maize for gene isolation by tagging and may prove similarly useful in other species. To test the feasibility of gene tagging with heterospecific transposons, we have examined three key genetic properties of a slightly modified Ac in tobacco. First, we show that frequencies of germinal excision of this Ac element from the antibiotic resistance gene streptomycin phosphotransferase can be comparable with or slightly lower than in maize. Second, we show that about half of the progeny carrying a germinal excision product also carry a transposed Ac. Last, we have mapped transposed Ac locations relative to the streptomycin transferase gene excision product and have shown that as in maize Ac in tobacco preferentially transposes to genetically linked sites.

Chromosome-breaking structure in maize involving a fractured Ac element

Chromosome breakage in maize can result from an interaction between certain transposable elements. When an Ac (Activator) element and a state I Ds (Dissociation) element are present together in the genome, either linked or unlinked, breaks occur regularly at the locus of the Ds element. We show here that breaks occur with high frequency at or near the locus of a structure consisting of a 2.5-kilobase (kb) terminally deleted or fractured Ac element very tightly linked to a second, intact 4.6-kb Ac element. This structure has the features of a macrotransposon and may behave like one. Loss of the tight linkage abolishes chromosome breakage. A model based on transposition of the macrotransposon is proposed to explain the chromosome-breaking properties of Ac and Ds.

Transposition Pattern of the Maize Element Ac from the Bz-M2(ac) Allele

The pattern of transposition of Ac from the mutable allele bz-m2(Ac) has been investigated. Stable (bz-s) and finely spotted (bz-m(F)) exceptions were selected from coarsely spotted bz-m2(Ac) ears. The presence or absence of a transposed Ac (trAc) in the genome was determined and, when present, the location of the trAc was mapped relative to the flanking markers sh and wx. The salient general features of Ac transposition to sites linked to bz are that the receptor sites tend to be clustered on either side of the bz donor site and that transposition is bidirectional and nonpolar. Thus, the symmetrical clustering in the distribution of receptor sites adjacent to bz differs from the asymmetrical clustering reported in 1984 for the P locus by I. M. GREENBLATT. Though Ac tends to transpose preferentially to closely linked sites, an appreciable fraction of Ac transpositions from bz-m2(Ac) is to unlinked sites: 41% among bz-s derivatives and 59% among bz-m(F) derivatives. Many transposition events among the bz-m(F) selections result in kernels carrying a genetically noncorresponding embryo. These can be interpreted as twin sectors arising at one of the megagametophytic mitoses. The bz locus data fit the earlier (1962) model of I. M. GREENBLATT and R. A. BRINK in which transposition takes place from a replicated donor site to either an unreplicated or replicated receptor site.

Two mutations in a maize bronze-1 allele caused by transposable elements of the Ac-Ds family alter the quantity and quality of the gene product

The Dissociation (Ds) mutant, Bz-wm, of the maize bronze-1 (bz) locus conditions a leaky phenotype. Plants carrying this mutant allele synthesize a low amount of an altered Bz gene product, which leads to reduced anthocyanin pigmentation in the seed. The molecular analysis reported here shows that the Bz-wm mutant has a 406-bp Ds1 insertion located 63 bp 5' to the start of Bz transcription. Furthermore, the Bz-wm allele contains three additional base pairs within the second exon, relative to the wild-type Bz allele. These additional nucleotides are believed to be derived from the 8-bp target site duplication created by an Activator (Ac) element in a previous allele in the series. The biochemical and molecular analyses of Bz-wm and revertants of Bz-wm indicate that the three additional nucleotides are responsible for the altered enzyme stability, while the Ds1 element affects the steady-state level of Bz-specific protein and RNA. Since the two mutations present in the Bz-wm mutant were each caused by the action of the Ac-Ds transposable element system, these results provide new insights into the ways that transposable elements can modify maize gene expression.

Sequence of three bronze alleles of maize and correlation with the genetic fine structure

The genomic sequences of three bronze alleles from Zea mays, Bz-McC, Bz-W22 and bz-R, are presented together with their flanking sequences. The bronze locus encodes UDPglucose flavonoid glucosyl-transferase (UFGT), an anthocyanin biosynthetic enzyme. The wild-type alleles Bz-McC and Bz-W22 condition purple phenotypes in the seed and plant, while bz-R conditions a bronze color. A full length cDNA corresponding to the Bz-McC allele was cloned and sequenced. Primer extension and RNase protection experiments were used to verify the 5' end of the bronze transcript. The Bz-McC allele has a 1416-bp coding region, a 100-bp intron and an approximately 83-bp 5' leader. Upstream of the message initiation site the sequences CTAACT and AATAAA occupy the positions where the eukaryotic consensus CCAAT and TATA boxes are normally found. The alleles Bz-McC and bz-R each have different large insertions with characteristics of transposable elements in their 5' flanking regions. The bz-R allele is distinguished by a 340-bp deletion starting within the intron and including 285 bp of the second exon. The Bz-McC and Bz-W22 isoalleles are known to differ in two genetically defined locations. The uts and uqv sites from the Bz-McC allele condition, respectively, lowered thermostability for the UFGT enzyme and increased amount of UFGT activity when compared with the corresponding sites in the Bz-W22 allele. The uts site maps to a region of the gene encoding two adjacent amino acid differences, either or both of which might alter the thermostability of the UFGT enzyme. The difference in UFGT levels conditioned by the uqv site is shown here to be correlated with variation in the bronze mRNA level. A likely cause of this decreased bronze mRNA level in Bz-W22 is a 6-bp duplication near the sequence CTAACT located 74 bp upstream of the bronze message initiation site. This region is therefore tentatively identified as the uqv site.

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

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 bz-m2 (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 bp 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.

Stability of deletion, insertion and point mutations at the bronze locus in maize

Phenotypic revertants from several kinds of mutations, including deletions, have been detected by pollen analysis at the wx and Adh loci in maize. Mutations in these genes give phenotypic revertants with median frequencies of 0.7 and 0.5×10(-5), respectively. However, the nature of such revertants can only be analyzed following their recovery from conventional matings. In the current study large seed populations derived from crosses involving several bz (bronze) locus mutations in maize were examined for reversion to a Bz (purple) expression. Deletion, insertion and point mutations were included in the study. Principally, over 2 million gametes of the bz-R mutation, which is shown here to be associated with a 340 base pair deletion within the transcribed region of the gene, have been screened for reversion. No revertants from it or any of the other bz mutations have been recovered, even though a total of almost 5 million gametes from homoallelic crosses have been examined to date. Results from seed analysis are discussed in reference to those from pollen analysis in maize.

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.

THE TRANSPOSABLE ELEMENT Ds AFFECTS THE PATTERN OF INTRAGENIC RECOMBINATION AT THE bz AND R LOCI IN MAIZE

Insertion of the transposable element Ds into either the bz or R locus affects intragenic recombination in various ways. We have examined here one aspect of this problem; namely, the distribution of flanking markers among intragenic recombinations produced by different types of heterozygotes carrying Ds insertion mutations. Heteroallelic combinations of a Ds insertion mutation and a mutation borne on a structurally normal chromosome generate a majority of intragenic recombinants of a crossover type. In contrast to this, most intragenic recombinants obtained from heterozygotes between two different Ds insertion mutations have a parental arrangement of outside markers. Therefore, the resolution of the recombination intermediate would appear to depend on the nature of the mutations in the heterozygote.

Viviparous-1 mutation in maize conditions pleiotropic enzyme deficiencies in the aleurone

The viviparous-1 (vp1) mutation in maize (Zea mays L.) conditions a unique pleiotropic phenotype: premature germination of the embryo and failure to synthesize anthocyanin (flavonoid) pigments in the aleurone. By using a B-A translocation, it is possible to analyze the basis for the anthocyaninless phenotype of vp1 in the absence of vivipary. Anthocyaninless vp1 aleurones were found to be deficient in at least three enzymes of flavonoid biosynthesis (phenylalanine ammonia lyase, chalcone synthase, and UDPG-flavonoid glucosyltransferase) as well as in several other metabolically unrelated enzymes that show pronounced increases in late stages of aleurone development. The set of structural genes encoding such enzymes is postulated to be under the regulation of the vpl gene.

INTERACTION AMONG C, R AND Vp IN THE CONTROL OF THE Bz GLUCOSYLTRANSFERASE DURING ENDOSPERM DEVELOPMENT IN MAIZE

The enzyme UPD glucose: flavonoid 3-0-glucosyltransferase (UFGT), involved in anthocyanin biosynthesis, is controlled by at least four genes (Bz, C, R and Vp) in the maize endosperm. Bz is the structural gene for the enzyme. Early in endosperm development, the enzyme is present in an uninduced low level that is independent of C, R and Vp, and dependent solely on Bz. Beginning at about the fourth week of development, C, R and Vp interact with each other to induce high levels of UFGT. The enzyme accumulates thereafter in normal endosperms, reaching its highest level at maturity. The nature of the developmental signal (s) controlled by C, R and Vp is discussed.

Genetic control of UDPglucose:flavonol 3-O-glucosyltransferase in the endosperm of maize

The enzyme UDPglucose:flavonol 3-O-glucosyltransferase is shown to be under the coordinate control of three genes involved in anthocyanin biosynthesis in the aleurone of maize: C, R, and BZ. Of the three, BZ appears to be the structural gene. Data presented here (dosage comparisons, induction in the mutant c-p, and effect of paramutation at R) indicate that the enzyme is inducible by substances resulting from the action of the C and R genes and that active forms of C and R are required for this induction. Mechanisms of regulation of the BZ gene by C and R are discussed.

DISPLACED AND TANDEM DUPLICATIONS IN THE LONG ARM OF CHROMOSOME 10 IN MAIZE

Lc, an anthocyanin pigmenting factor mapping somewhat more than one unit distal to R, is borne on a chromosomal segment which is homologous with part of the R-r:standard duplicated segment. Deficiencies and tandem duplications of the R to Lc region arise from exchanges within these obliquely paired homologous segments. The deficiencies are transmitted with a high, although reduced, frequency by the male gametophyte and are homozygous viable. Yet, the R to Lcregion is not duplicated either proximal to R or distal to Lc. Thus the Lc-marked segment and either the P- or the S-marked segment of R-r constitute a displaced duplication. Such an arrangement can initiate a tandem and displaced duplication cycle.——No evidence was obtained for fractionation of the compound phenotype conditioned by Lc.

RECONSTITUTION OF THE Rr COMPOUND ALLELE IN MAIZE

The Rr:standard allele in maize, which conditions anthocyanin pigmentation in plant and seed tissues in the presence of appropriate complementary factors, is associated with a tandem duplication. The proximal member of the duplication carries P, the plant pigmenting determiner and the distal member member carries S, the seed pigmenting determiner. Derivatives from Rr that have lost S function are designated rr. They represent either losses of the distal member of the duplication (P derivatives) or mutations of S to s (P s). Derivatives that have lost P function are designated Rg, and represent either losses of the proximal member of the duplication (S derivatives) or mutations of P to p (p S).—All four possible types of rr/Rg heterozygotes were tested for their capacity to yield Rr reconstitution by crossing over. No Rr derivatives were obtained from P/S heterozygotes, a result consistent with the view that P and S occupy corresponding positions in homologous chromosome segments. Rr reconstitution was detected in both tandem duplication heterozygotes P s/S and P/p S, and was found to be about ten times more frequent in the latter. The ratio of Rr reconstitution in the two heterozygotes is a function of position of the anthocyanin marker within the duplicated segment. The data from these heterozygotes allow one to measure the distance between P and S, that is to say, the genetic length of the duplicated segment. This distance was found to be 0.16 map units. The highest frequency of Rr reconstitution was obtained from P s/p S heterozygotes, since direct pairing (see PDF) as well as the p//s type of displaced pairing have the potential to produce Rr derivatives. One of the Rg derivatives used in this study, Rg  6, was found to back-mutate in some sublines to Rr. The basis for this instability remains unknown.