Genetic factors required to maintain repression of a paramutagenic maize pl1 allele.

A genetic screen identified two novel gene functions required to maintain mitotically and meiotically heritable gene silencing associated with paramutation of the maize purple plant 1 (pl1) locus. Paramutation at pl1 leads to heritable alterations of pl1 gene regulation; the Pl-Rhoades (Pl-Rh) allele, which typically confers strong pigmentation to juvenile and adult plant structures, changes to a lower expression state termed Pl'-mahogany (Pl'). Paramutation spontaneously occurs at low frequencies in Pl-Rh homozygotes but always occurs when Pl-Rh is heterozygous with Pl'. We identified four mutations that caused increased Pl' pigment levels. Allelism tests revealed that three mutations identified two new maize loci, required to maintain repression 1 (rmr1) and rmr2 and that the other mutation represents a new allele of the previously described mediator of paramutation 1 (mop1) locus. RNA levels from Pl' are elevated in rmr mutants and genetic tests demonstrate that Pl' can heritably change back to Pl-Rh in rmr mutant individuals at variable frequencies. Pigment levels controlled by two pl1 alleles that do not participate in paramutation are unaffected in rmr mutants. These results suggest that RMR functions are intimately involved in maintaining the repressed expression state of paramutant Pl' alleles. Despite strong effects on Pl' repression, rmr mutant plants have no gross developmental abnormalities even after several generations of inbreeding, implying that RMR1 and RMR2 functions are not generally required for developmental homeostasis.

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 alters regulatory control of the maize pl locus.

The maize purple plant (pl) locus encodes a transcription factor required for anthocyanin pigment synthesis in vegetative and floral tissues. The strongly expressed Pl-Rhoades (Pl-Rh) allele is unstable, spontaneously changing to weaker expression states (Pl') at low frequencies and exclusively changing to Pl' in Pl'/Pl-Rh heterozygotes. The weakly expressed Pl' state is mitotically and meiotically stable, yet reversible. This type of allele-dependent, heritable alteration of gene control is called paramutation. Expression studies herein demonstrate that visible differences in anthocyanin pigment levels mirror pl RNA abundance and that pl paramutation is associated with reduced transcription of the pl gene. This transcriptional alteration is accompanied by acquisition of light-dependent regulation. Restriction endonuclease mapping indicates that these changes in pl gene regulation are not associated with detectable DNA alterations or with extensive changes in cytosine methylation patterns. Genetic tests show that Pl-Blotched (Pl-Bh), a structurally similar pl allele encoding an identical pl RNA and PL protein, does not participate in pl paramutation. This result suggests that if cis-acting sequences are required for pl paramutation they are distinct from the protein coding and immediately adjacent regions. A model is discussed in which pl paramutation results in heritable changes of chromatin structure that fundamentally alter regulatory interactions occurring during plant development.

Epigenetic allelic states of a maize transcriptional regulatory locus exhibit overdominant gene action.

Using alleles of the maize purple plant locus (pl), which encodes a transcriptional regulator of anthocyanin pigment synthesis, we describe a case of single-locus heterosis, or overdominance, where the heterozygote displays a phenotype that is greater than either homozygote. The Pl-Rhoades (Pl-Rh) allele is subject to epigenetic changes in gene expression, resulting in quantitatively distinct expression states. Allelic states with low-expression levels, designated Pl'-mahogany (Pl'-mah), are dominant to the high-expression state of Pl-Rh. Pl'-mah states retain low-expression levels in subsequent generations when homozygous or heterozygous with Pl-Rh. However, Pl'-mah alleles frequently exhibit higher expression levels when heterozygous with other pl alleles; illustrating an overdominant allelic relationship. Higher expression levels are also observed when Pl'-mah is hemizygous. These results suggest that persistent allelic interactions between Pl'-mah and Pl-Rh are required to maintain the low-expression state and that other pl alleles are missing sequences required for this interaction. The Pl-Rh state can be sexually transmitted from Pl'-mah/pl heterozygotes, but not from Pl'-mah hemizygotes, suggesting that fixation of the high-expression state may involve synapsis. The existence of such allele-dependent regulatory mechanisms implicates a novel importance of allele polymorphisms in the genesis and maintenance of genetic variation.

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.

Allelic interactions heritably alter the activity of a metastable maize pl allele.

The maize pl locus encodes a transcriptional activator of anthocyanin biosynthetic genes. The Pl-Rhoades (Pl-Rh) allele confers robust purple anthocyanin pigment in several tissues. Spontaneous derivatives of Pl-Rh, termed Pl'-mahogany (Pl'-mah), arise that confer reduced pigment and are meiotically heritable. These derivatives influence other Pl-Rh alleles such that only Pl'-mah alleles are transmitted form a Pl-Rh/Pl'mah heterozygote. Genetic crosses establish that chromosomal segregation distortion does not explain this exclusive transmission and suggest that Pl-Rh invariably changes to Pl'-mah when exposed to Pl'-mah. Such behavior is a hallmark of paramutation. Cosegregation experiments demonstrate that this paramutagenic activity is genetically linked to the pl locus. By visually quantifying pl action through successive crosses, we find that phenotypic expression is inversely related to paramutation at two other maize loci, b and r. Previous analysis of b and r paramutation revealed extensive differences and led to suggestions of distinct molecular mechanisms. Consideration of the common features of all three systems reinvigorates the interpretation that the mechanistic processes of these three allelic interactions are similar.

Transgenic analysis of a hybrid poplar wound-inducible promoter reveals developmental patterns of expression similar to that of storage protein genes.

The wound-inducible win3 multigene family from hybrid poplars (Populus trichocarpa x Populus deltoides) encodes proteins with structural similarities with Kunitz-type protease inhibitors (H.D. Bradshaw Jr., J.B. Hollick, T.J. Parsons, H.R.G. Clarke, M.P. Gordon [1990] Plant Mol Biol 14: 51-59), and at least one member, win3.12, is transcribed de novo in the injured and uninjured leaves of wounded trees (J.B. Hollick, M.P. Gordon [1993] Plant Mol Biol 22: 561-572). A previous study demonstrated that 1352 bp of 5' flanking DNA from the win3.12 gene confers local wound-regulated expression of the beta-glucuronidase gene in transgenic tobacco (Nicotiana tabacum cv Xanthi n.c.) (J.B. Hollick, M.P. Gordon [1993] Plant Mol Biol 22: 561-572). We extend this transgenic analysis here by examining the developmental regulation and systemic wound induction conferred by the same transgene construct in tobacco. Biochemical and histochemical surveys of beta-glucuronidase activity are described for four, independent transgenic lines. The observed spatial and temporal expression patterns coincide with dormant storage tissues and with previously described expression patterns for both seed and vegetative storage protein genes. Developmental northern blot analysis of win3 RNA levels in poplar seeds confirms that proper temporal expression of the reporter gene is maintained during tobacco seed maturation. These results demonstrate that a putative Kunitz-type protease inhibitor can be wound inducible in addition to being expressed in developing seeds.

A poplar tree proteinase inhibitor-like gene promoter is responsive to wounding in transgenic tobacco.

Wounding of poplar trees leads to the accumulation of several mRNA species that encode proteins with putative defensive function. One class of wound-induced poplar RNA (win3) has amino acid sequence similarity to Kunitz-type trypsin inhibitors. Northern blots and cDNA sequencing show that several win3 mRNAs accumulate in the uninjured leaves of wounded trees. We report further characterization of the win3 family including sequence comparisons, gene family organization, and the identification of one win3 member that is transcriptionally activated in response to mechanical wounding. We also show that 1.5 kb of 5'-flanking sequence of one win3 member (win3.12) is sufficient to confer wound-regulated expression of a beta-D-glucuronidase (GUS) reporter gene in transgenic tobacco. Annual herbaceous plants such as tobacco can thus be used to study the expression of genes from a perennial woody angiosperm.

Systemically wound-responsive genes in poplar trees encode proteins similar to sweet potato sporamins and legume Kunitz trypsin inhibitors.

When the lower leaves of hybrid poplar trees are mechanically wounded, several novel mRNAs accumulate in the unwounded upper leaves (Parsons TJ, Bradshaw HD, Gordon MP: Systemic accumulation of specific mRNAs in response to wounding in poplar trees, Proc Natl Acad Sci USA, in press). A partial cDNA clone corresponding to a transcript from the wound-responsive gene designated win 3 (wound-inducible) has been cloned by differential hybridization to 32P-labelled cDNA from the leaves of wounded trees. Northern blots show a large accumulation of win 3 transcripts in the unwounded leaves of wounded trees. Southern blot analysis of poplar DNA suggests that win 3 is a member of a multigene family. The nucleotide sequences of several win 3 cDNA clones have been determined, indicating that at least three win 3 gene family members are transcribed. A genomic clone of a win 3 gene family member has been isolated and a 1.5 kb Hind III fragment containing the predicted protein-coding and 5' upstream regions has been sequenced. The putative win 3 gene product is similar to the major soluble proteins of sweet potato tubers, sporamin A and sporamin B. Both Win3 and the sporamins share significant amino acid sequence identity with Kunitz-type trypsin inhibitors from legume seeds. The Kunitz family of proteinase inhibitors thus joints three other proteinase inhibitor families which are systemically responsive to wounding.