RECONSTITUTION OF THE Rr COMPOUND ALLELE IN MAIZE

Probing the component structure of a maize gene with transposable elements

Three instances of R gene instability were found in maize stocks carrying the controlling elements Dissociation (Ds) and Modulator (Mp). In each, Ds or a Ds-like element had transposed to R, inhibiting kernel pigmentation irregularly. When Mp was removed from the genome, R expression stabilized at lowt to intermediate levels. Strong pigmenting action was restored through recombination in heterozygotes of the three new forms with an R allele that specifies only plant pigmentation. The sites of Ds insertion mapped distal to the region that specifies seed versus plant expression. The evidence suggests that an R functional unit consists of one component that both governs tissue-specific expression and another that is common to alleles of different tissue-specific activities.

Unequal sister chromatid and homolog recombination at a tandem duplication of the A1 locus in maize

Tandemly arrayed duplicate genes are prevalent. The maize A1-b haplotype is a tandem duplication that consists of the components, alpha and beta. The rate of meiotic unequal recombination at A1-b is ninefold higher when a homolog is present than when it is absent (i.e., hemizygote). When a sequence heterologous homolog is available, 94% of recombinants (264/281) are generated via recombination with the homolog rather than with the sister chromatid. In addition, 83% (220/264) of homolog recombination events involved alpha rather than beta. These results indicate that: (1) the homolog is the preferred template for unequal recombination and (2) pairing of the duplicated segments with the homolog does not occur randomly but instead favors a particular configuration. The choice of recombination template (i.e., homolog vs. sister chromatid) affects the distribution of recombination breakpoints within a1. Rates of unequal recombination at A1-b are similar to the rate of recombination between nonduplicated a1 alleles. Unequal recombination is therefore common and is likely to be responsible for the generation of genetic variability, even within inbred lines.

pl-bol3, a complex allele of the anthocyanin regulatory pl1 locus that arose in a naturally occurring maize population

The pl1 gene encodes a MYB-related transcriptional activator committed to the regulation of anthocyanin biosynthesis in maize. Here, we report the genetic and molecular characterisation of pl-bol3, an Andean allele displaying features that make it different from all the known pl1 alleles. pl-bol3 has partial, light-independent expression, and it is active mainly in the juvenile phase of growth. It has a complex molecular structure, containing multiple pl1 gene copies, thus being the first complex locus discovered in the c1/pl1 family. Although the composite genes of the complex locus encode proteins identical to other functional PL1 proteins, the putative promoters of the pl-bol3 gene are different from the promoters of Pl-Rhoades (Pl-Rh) and pl1 sun-red alleles. The intensity and the tissue specificity of anthocyanin production directed by pl-bol3 differ significantly from that of Pl-Rh and the original pl-W22, and are specified by the interaction of pl-bol3 with the different r1/b1 gene family members and the competence of pl-bol3 to different pigment tissues. This allele represents a natural example of gene duplication and diversification of expression, giving rise to a significant change in phenotype and, in this way, is analogous to the complex r1 locus in maize. Analysis of the pl-bol3 allele contributes to understanding the generation of diversity associated with multiple-copy genes and the molecular basis of allele-specific gene expression.

The identification and characterization of two dominant r1 haplotype-specific inhibitors of aleurone color in Zea mays

We report the identification and characterization of two novel dominant inhibitors of aleurone color in Zea mays that interact with specific haplotypes of the r1 locus. One inhibitor locus, inr1 (inhibitor of r1 aleurone color 1), maps to the long arm of chromosome 10, distal to the TB-10L19 breakpoint and tightly linked to dull1, and the second inhibitor locus, inr2 (inhibitor of r1 aleurone color 2), maps to the long arm of chromosome 9. Dominant inhibitory alleles of inr1 and inr2 act by suppressing aleurone color conditioned by certain r1 haplotypes. Two haplotypes, R1-ch:Stadler and R1-Randolph, exhibit nearly complete suppression of aleurone color in the presence of inhibitory alleles of inr1 or inr2. Two members of the R1-d class of haplotypes, R1-d:Catspaw and R1-d:Arapaho, show partial suppression. Other haplotypes tested were not visibly affected. The response of r1 haplotypes to inhibitory inr1 and inr2 alleles provides another means of analyzing the complex behavior of the seed color components of r1 haplotypes. Possible mechanisms of action of inr1 and inr2 are discussed.

A maize r1 gene is regulated post-transcriptionally by differential splicing of its leader

Anthocyanin biosynthesis in Zea mays is controlled by regulatory genes of the r1/b1 family that encode bHLH transcription factors. Analysis of the 381 nucleotide leader sequence of a member of this family, Sn, discloses the presence of five ATG triplets upstream of the coding region and three upstream open reading frames (uORFs) of 38, 15 and 13 amino acids respectively. RT-PCR studies revealed that a splicing event occurs in the leader region in the different tissues tested. Splicing deletes 146 nucleotides which include uORF2 and uORF3. By trans-activation experiments in maize protoplasts we find that the spliced leader, compared to the non-spliced one, reduces the number of pigmented protoplasts by four-fold. We suggest a multilevel regulation of the Sn transcription factor acting not only at the transcriptional but also at the post-transcriptional level.

Structural features and methylation patterns associated with paramutation at the r1 locus of Zea mays

In paramutation, two alleles of a gene interact and, during the interaction, one of them becomes epigenetically silenced. The various paramutation systems that have been studied to date exhibit intriguing differences in the physical complexity of the loci involved. B and Pl alleles that participate in paramutation are simple, single genes, while the R haplotypes that participate in paramutation contain multiple gene copies and often include rearrangements. The number and arrangement of the sequences in particular complex R haplotypes have been correlated with paramutation behavior. Here, the physical structures of 28 additional haplotypes of R were examined. A specific set of physical features is associated with paramutability (the ability to be silenced). However, no physical features were strongly correlated with paramutagenicity (the ability to cause silencing) or neutrality (the inability to participate in paramutation). Instead, paramutagenic haplotypes were distinguished by high levels of cytosine methylation over certain regions of the genes while neutral haplotypes were distinguished by lack of C-methylation over these regions. These findings suggest that paramutability of r1 is determined by the genetic structure of particular haplotypes, while paramutagenicity is determined by the epigenetic state.

The developmental expression of the maize regulatory gene Hopi determines germination-dependent anthocyanin accumulation

The Hopi gene is a member of the maize r1 gene family. By genetic and molecular analyses we report that Hopi consists of a single gene residing on chromosome 10 approximately 4.5 cM distal to r1. Hopi conditions anthocyanin deposition in aleurone, scutellum, pericarp, root, mesocotyl, leaves, and anthers, thus representing one of the broadest specifications of pigmentation pattern reported to date of all the r1 genes. A unique feature of the Hopi gene is that seeds are completely devoid of pigment at maturity but show a photoinducible germination-dependent anthocyanin accumulation in aleurone and scutellum. Our analysis has shown that the Hopi transcript is not present in scutellum of developing seeds but is induced only upon germination and that the simultaneous presence of both C1 and Hopi mRNAs is necessary to achieve A1 activation in scutella. We conclude that the expression pattern of the Hopi gene accounts for the germination-dependent anthocyanin synthesis in scutella, whereas the developmental competence of germinating seeds to induce anthocyanin production in scutella results from the combination of the light-inducible expression of C1 and the developmentally regulated expression of the Hopi gene.

Light-Dependent Spatial and Temporal Expression of Pigment Regulatory Genes in Developing Maize Seeds

Both light and developmental stimuli are directly involved in the regulation of plant gene expression. In maize, activation of the anthocyanin pathway represents an excellent model system for studying the interactions between an external factor, such as light, and internal factors that regulate plant and seed development. By analyzing in detail the aleurone and pericarp seed layers, different developmental windows for light have been found in the two tissues[mdash]the former in the advanced stages of development and the latter in the early stages of seed development. Transcriptional control of the structural genes involved in anthocyanin deposition within the pericarp is known to be exerted by the Sn and pl genes, whereas the aleurone is controlled by the R and C1 regulatory genes. By using in situ hybridization analysis, we detected tissue-specific expression of Sn and R in the seed layers, revealing a correlation between structural gene activation and anthocyanin accumulation. In addition, RNA gel blot analysis revealed that Sn expression is enhanced by light, whereas the R gene expression is not. However, the light-induced expression of the myb-type genes C1 and pl, detected by reverse transcriptase-polymerase chain reaction, was found to be the limiting factor for conferring the developmental competence of the pericarp and the aleurone layers to light responsiveness.

Insertions of a novel class of transposable elements with a strong target site preference at the r locus of maize

The r locus of maize regulates anthocyanin synthesis in various tissues of maize through the production of helix-loop-helix DNA binding proteins capable of inducing expression of structural genes in the anthocyanin biosynthetic pathway. The complex r variant, R-r: standard (R.r), undergoes frequent mutation through a variety of mechanisms including displaced synapsis and crossing over, and intrachromosomal recombination. Here we report a new mechanism for mutation at the R-r complex: insertion of a novel family of transposable elements. Because the elements were first identified in the R-p gene of the R-r complex, they have been named P instability Factor (PIF). Two different PIF elements were cloned and found to have identical sequences at their termini but divergent internal sequences. In addition, the PIF elements showed a marked specificity of insertion sites. Six out of seven PIF-containing derivatives examined had an element inserted at an identical location. Two different members of the PIF element family were identified at this position. The seventh PIF-containing derivative examined had the element inserted at a distinct position within r. Even at this location, however, the element inserted into a conserved target sequence. The timing of PIF excision is unusual. Germinal excision rates can range up to several percent of progeny. Yet somatic sectors are rare, even in lines exhibiting high germinal reversion rates.

Molecular homology among members of the R gene family in maize

The R gene family determines the timing, distribution and amount of anthocyanin pigmentation in maize. This family comprises a set of regulatory genes, consisting of a cluster of several elements at the R locus, on chromosome 10, the Lc and Sn gene lying about two units R distal and B on chromosome 2. Each gene determines a tissue-specific pigmentation of different parts of the seed and plant. The proposed duplicated function of R, Sn, Lc and B loci is reflected in cDNA sequence similarity. In this paper an extensive analysis of the predicted proteins of the R, Sn, Lc and B genes together with a search for putative sites of post-translational modification is reported. A comparison with the prosite database discloses several N-glycosylation and phosphorylation sites, as well as the basic Helix-Loop-Helix (HLH) domain of transcriptional activators. Sn, Lc, and R-S show a high conservation of these sites, while B is more divergent. Analysis of the 5' leader of mRNA sequences discloses the presence of five ATG triplets with two upstream open reading frames (uORFs) of 38 and 15 amino acids and a loop structure indicating a possible mechanism of control at the translational level. It is conceivable that possible mechanisms acting at the translational and post-translational level could modulate the expression and the activation of these transcription factors. Northern analysis of various tissues of different R alleles highlights a strict correlation between pigment accumulation in different tissues and the expression of the regulatory and structural genes suggesting that the pattern of pigmentation relies on a mechanism of differential expression of the members of the R family. Analysis of the Sn promoter discloses the presence of several sequences resembling binding sites of known transcription factors (as GAGA and GT) that might be responsible for the spatial and light-induced expression of this gene. Two regions include a short sequence homologous to the consensus binding site of the B-HLH domain suggesting a self-regulatory control of the Sn gene.

Meiotic instability of the R-r complex arising from displaced intragenic exchange and intrachromosomal rearrangement

The R complex of Zea mays encodes a tissue-specific transcriptional activator of the anthocyanin pigment biosynthetic pathway. Certain R alleles comprise two genetically distinct components that confer the plant (P) and seed (S) aspects of the pigmentation pattern. These alleles are meiotically unstable, losing (P) or (S) function, often accompanied by exchange of flanking markers. We show that the (P) component consists of a single gene within the R-r complex, whereas the (S) component is part of a more complex arrangement of multiple R genes or gene subfragments. A third, cryptic region of the complex, termed (Q), consists of a truncated R sequence. The analysis of R-r crossover derivative alleles shows they arise from unequal exchange between the (P) gene and one of several distinct regions of the R-r complex. Restriction site polymorphisms were used to show that most of these unequal exchanges are intragenic. The frequency of displaced intragenic recombination is comparable to previous estimates for intragenic recombination in maize involving genes that are not duplicated. These exchange events have been used to determine the arrangement of components within the complex and their orientation in the chromosome. We also show that localized rearrangements in the (P) or (S) components are responsible for noncrossover derivative alleles. The organization of R-r has implications for these noncrossover derivatives and models for their origin are discussed.

Genetic and molecular analysis of Sn, a light-inducible, tissue specific regulatory gene in maize

The Sn locus of maize is functionally similar to the R and B loci, in that Sn differentially controls the tissue-specific deposition of anthocyanin pigments in certain seedling and plant cells. We show that Sn shows molecular similarity to the R gene and have used R DNA probes to characterize several Sn alleles. Northern analysis demonstrates that all Sn alleles encode a 2.5 kb transcript, which is expressed in a tissue-specific fashion consistent with the distribution of anthocyanins. Expression of the Sn gene is light-regulated. However, the Sn: bol3 allele allows Sn mRNA transcription to occur in the dark, leading to pigmentation in dark-grown seedlings and cob integuments. We report the isolation of genomic and cDNA clones of the light-independent Sn: bol3 allele. Using Sn cDNA as a probe, the spatial and temporal expression of Sn has been examined. The cell-specific localization of Sn mRNA has been confirmed by in situ hybridization using labelled antisense RNA probes. According to its proposed regulatory role, expression of Sn precedes and, in turn, causes a coordinate and tissue-specific accumulation of mRNA of structural genes for pigment synthesis and deposition, such as A1 and C2. The functional and structural relationship between R, B, Lc and Sn is discussed in terms of an evolutionary derivation from a single ancestral gene which gave rise this diverse gene family by successive duplication events.

Sn, a light-dependent and tissue-specific gene of maize: the genetic basis of its instability

The genetic system under investigation is defined by three major components: a gene, Sn, conferring tissue specific anthocyanin accumulation in different plant regions, light, required for color development in competent tissues, and another gene, Pl, substituting for light in its capacity to elicit pigment production. Attention is given in this paper to an Sn allele, symbolized Sn:bol3, capable of some constitutive pigmentation in seedlings and seed integuments. Sn:bol3 confers a higher pigment potential than the other alleles and is unstable. Its instability relates to its frequent changes from an original condition, indicated as Sn-s, to Sn-w, where -s and -w stand for strong and weak and refer to the two levels of seedling pigmentation. Weak derivatives arise spontaneously at a high frequency in homo- and heterozygous Sn:bol3 genotypes. In the latter, weak derivatives are also recovered on the chromosome originally devoid of Sn as if the heterozygous association had promoted "contamination" of one chromosome (recipient) with Sn coming from the other (donor). If the two chromosomes in the heterozygote are marked with contrasting alleles of R, a gene lying about two crossover units proximal to Sn, it appears that the R constitution of the recipient chromosome affects their constitution. Presence of R-r in fact leads to changes of both chromosomes in terms of Sn constitution, resulting in a majority of nonparental chromosomes, R-r Sn and r Sn-w or r sn, while replacement of R-r with R-g, a mutant derivative of R-r, leads to a drastic reduction in the yield of nonparental chromosomes.(ABSTRACT TRUNCATED AT 250 WORDS)