The maize Myb transcription factor C1 depends on the basic helix-loop-helix (bHLH) proteins R or B for regulatory function, but the closely related Myb protein P does not. We have used the similarity between the Myb domains of C1 and P to identify residues that specify the interaction between the Myb domain of C1 and the N-terminal region of R. Substitution of four predicted solvent-exposed residues in the first helix of the second Myb repeat of P with corresponding residues from C1 is sufficient to confer on P the ability to physically interact with R. However, two additional Myb domain amino acid changes are needed to make the P regulatory activity partially dependent on R in maize cells. Interestingly, when P is altered so that it interacts with R, it can activate the Bz1 promoter, normally regulated by C1 ؉ R but not by P. Together, these findings demonstrate that the change of a few amino acids within highly similar Myb domains can mediate differential interactions with a transcriptional coregulator that plays a central role in the regulatory specificity of C1, and that Myb domains play important roles in combinatorial transcriptional regulation. Combinatorial interactions between transcription factors are of central importance to regulation of gene expression in eukaryotes. These interactions can either modulate transcription factor activity or contribute to the biological specificity of factors with very similar DNA-interaction motifs. Elucidation of the mechanisms by which proteins with very similar DNA-binding domains achieve regulatory specificity remains a fundamental question in biology today.Proteins containing the Myb-homologous DNA-binding domain are widespread in eukaryotes (reviewed in refs. 1 and 2). The vertebrate c-myb gene plays an essential regulatory role in the proliferation and differentiation of hematopoietic cells. Besides c-myb, at least two other myb-related genes (A-myb and B-myb) are present in vertebrates (3). The products of these genes have Myb domains, each consisting of three head-to-tail Myb motifs (R1, R2, and R3). Oncogenic versions of c-myb, such as v-myb, contain only R2 and R3, as do hundreds of plant Myb-domain proteins (4). Myb domains formed by the R2 and R3 Myb motifs bind DNA. Each Myb motif contains three ␣-helices, and the third helix of each Myb motif makes sequencespecific DNA contacts. The second and third helices of each Myb motif form a helix-turn-helix structure when bound to DNA, similar to motifs found in the repressor and in homeo domains (5). In addition to their well-established roles in DNA binding, Myb domains are also emerging as important protein-protein interaction motifs. These Myb domain-mediated proteinprotein interactions play key roles in the biological specificity of the corresponding factors (6-13). However, the mechanisms by which protein-protein interactions contribute to the regulatory specificity of Myb domain proteins are poorly understood.In f lowering plants, several hundred genes containing the conserved Myb DNA-binding domain have b...
Allelic expression variation of nonimprinted autosomal genes has recently been uncovered in mouse hybrids and humans. The allelic expression variation is attributed to differences in noncoding DNA sequences and does not involve epigenetic regulation or gene imprinting. This expression variation is suggested to play important roles in determining phenotypic diversity. Virtually nothing is known about such allele-specific expression variation in a hybrid plant where two alleles are compared in the same genetic context. We examined parental transcript accumulation in maize (Zea mays) hybrids using allele-specific RT-PCR analysis. Among 15 genes analyzed, 11 showed differences at the RNA level, ranging from unequal expression of the two alleles (biallelic) to expression of a single allele (monoallelic). Maternal or paternal transmission had little effect on the allele-specific transcript ratio of nearly all genes analyzed, suggesting that parent-of-origin effect was minimal. We analyzed the allelic difference in genetically contrasting hybrids and hybrids under high planting density and drought stress. Whereas a genetically improved modern hybrid expressed both alleles, a less improved old hybrid frequently showed mono-allelic expression. Furthermore, the two alleles in the hybrid responded differentially to abiotic stresses. The results of allele-specific regulation in different tissues in responding to environment and stress suggest an unequivalent function of the parental alleles in the hybrid, which may have an impact on heterosis.
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