mediator of paramutation1 is required for establishment and maintenance of paramutation at multiple maize loci.

Paramutation is the directed, heritable alteration of the expression of one allele when heterozygous with another allele. Here, the isolation and characterization of a mutation affecting paramutation, mediator of paramutation1-1 (mop1-1), are described. Experiments demonstrate that the wild-type gene Mop1 is required for establishment and maintenance of the paramutant state. The mop1-1 mutation affects paramutation at the multiple loci tested but has no effect on alleles that do not participate in paramutation. The mutation does not alter the amounts of actin and ubiquitin transcripts, which suggests that the mop1 gene does not encode a global repressor. Maize plants homozygous for mop1-1 can have pleiotropic developmental defects, suggesting that mop1-1 may affect more genes than just the known paramutant ones. The mop1-1 mutation does not alter the extent of DNA methylation in rDNA and centromeric repeats. The observation that mop1 affects paramutation at multiple loci, despite major differences between these loci in their gene structure, correlations with DNA methylation, and stability of the paramutant state, suggests that a common mechanism underlies paramutation. A protein-based epigenetic model for paramutation is discussed.

Paramutation in maize.

Paramutation is a heritable change in gene expression induced by allele interactions. This review summarizes key experiments on three maize loci, which undergo paramutation. Similarities and differences between the phenomenology at the three loci are described. In spite of many differences with respect to the stability of the reduced expression states at each locus or whether paramutation correlates with DNA methylation and repeated sequences within the loci, recent experiments are consistent with a common mechanism underlying paramutation at all three loci. Most strikingly, trans-acting mutants have been isolated that prevent paramutation at all three loci and lead to the activation of silenced Mutator transposable elements. Models consistent with the hypothesis that paramutation involves heritable changes in chromatin structure are presented. Several potential roles for paramutation are discussed. These include localizing recombination to low-copy sequences within the genome, establishing and maintaining chromatin domain boundaries, and providing a mechanism for plants to transmit an environmentally influenced expression state to progeny.

Paramutation and related allelic interactions.

Paramutation is an allelic interaction that results in meiotically heritable changes in gene expression. Until recently, the few documented cases in higher plants seemed unusual and rare. This perception is rapidly fading because of the discovery of related examples and the growing recognition of epigenetic changes in a wide variety of biological systems.

Developmental analysis of teosinte glume architecture1: A key locus in the evolution of maize (Poaceae).

A key event in the evolution of maize from teosinte was a reduction in the cupulate fruitcase and softening of the glumes, which increased the accessibility of kernels for harvest. The teosinte glume architecture1 (tga1) locus largely controls this difference between maize and teosinte, and thus may have played a pivotal role in maize evolution. The teosinte allele (tga1+teosinte) lengthens inflorescence internodes, shortens rachillae, and makes glumes longer, thicker, and harder. Developmental characterization of morphometric traits reveals that differences among genotypes are apparent early in female inflorescence development. Increased hardening in glumes homozygous for tga1+teosinte is correlated with a thicker abaxial mesoderm of lignified cells. Silica deposition in the abaxial epidermal cells of the glumes is also affected. In the maize background, glumes homozygous for tga1+teosinte deposit silica in both the short and long cells of the glume epidermis, whereas glumes homozygous for the maize allele (Tga1+Maize) concentrate silica only in the short cells. Silica deposition also appears to be affected by genetic background. The effects of tga1 appear largely to explain the differences in glume induration between maize and teosinte. The diverse pleiotropic effects of tga1 suggest that it is regulatory in nature.

Teosinte glume architecture 1: A Genetic Locus Controlling a Key Step in Maize Evolution.

Teosinte, the probable progenitor of maize, has kernels that are encased in hardened fruitcases, which interfere with the use of the kernels as food. Although the components of the fruitcase are present in maize, their development is disrupted so that the kernels are not encased as in teosinte but exposed on the ear. The change from encased to exposed kernels represents a key step in maize evolution. The locus that largely controls this morphological difference between maize and teosinte, teosinte glume architecture 1, is described and genetically mapped.