Analysis of a chemical plant defense mechanism in grasses.

In the Gramineae, the cyclic hydroxamic acids 2,4-dihydroxy-1, 4-benzoxazin-3-one (DIBOA) and 2,4-dihydroxy-7-methoxy-1, 4-benzoxazin-3-one (DIMBOA) form part of the defense against insects and microbial pathogens. Five genes, Bx1 through Bx5, are required for DIBOA biosynthesis in maize. The functions of these five genes, clustered on chromosome 4, were demonstrated in vitro. Bx1 encodes a tryptophan synthase alpha homolog that catalyzes the formation of indole for the production of secondary metabolites rather than tryptophan, thereby defining the branch point from primary to secondary metabolism. Bx2 through Bx5 encode cytochrome P450-dependent monooxygenases that catalyze four consecutive hydroxylations and one ring expansion to form the highly oxidized DIBOA.

Genetic characterization of the Mutator system in maize: behavior and regulation of Mu transposons in a minimal line.

Most Mutator lines of maize harbor several different classes of Mu transposons, each of which may be present in high copy number. The regulatory element is also often found in high copy number, and it is this element's behavior that is presumed to cause the non-Mendelian inheritance of Mutator activity. Using a very simple Mutator line, we demonstrate tha MuDR-1, a regulator of the Mutator system, can functionally replace standard non-Mendelian Mutator activity and that MuDR-1 is associated with the loss of methylation of the termini of another Mu transposon. Further, we show that Mu transposons can transpose duplicatively, that reinsertion tends to be into unlinked sites, and that MuDR-1 frequently suffers deletions. Changes in chromosomal position and the mode of sexual transmission are shown to be associated with changes in the frequency of MuDR-1 duplication and with the activity of MuDR-1 as monitored by the excision frequency of a reporter transposon of the Mu family, Mu1. Our data are derived from a Minimal Mutator Line in which there are relatively few Mu transposons, including one MuDR-1 regulator and as few as one Mu1 reporter. The seemingly enigmatic results that have been obtained using more complicated Mu genotypes are reinterpreted using simple Mendelian principles. We have borrowed a gap-repair model from Drosophila biologists to explain both duplications and deletions of MuDR-1.

Identification of a regulatory transposon that controls the Mutator transposable element system in maize.

The Mutator system of maize consists of more than eight different classes of transposable elements each of which can be found in multiple copies. All Mu elements share the approximately 220-bp terminal inverted repeats, whereas each distinct element class is defined by its unique internal sequences. The regulation of instability of this system has been difficult to elucidate due to its multigenic inheritance. Here we present genetic experiments which demonstrate that there is a single locus, MuR1, which can regulate the transposition of Mu1 elements. We describe the cloning of members of a novel class of Mu elements, MuR, and demonstrate that a member of the class is the regulator of Mutator activity, MuR1. This conclusion is based on several criteria: MuR1 activity and a MuR-homologous restriction fragment cosegregate; when MuR1 undergoes a duplicative transposition, an additional MuR restriction fragment is observed, and MuR1 activity and the cosegregating MuR fragment are simultaneously lost within clonal somatic sectors. In addition, the MuR element hybridizes to transcripts in plants with Mutator activity. Our genetic experiments demonstrate that the MuR1 transposon is necessary to specify Mutator activity in our lines.

Cytosine methylation in gene-silencing mechanisms.

Cytosine methylation is associated with gene-silencing mechanisms in a number of eukaryotic organisms. Recent studies directed at the involvement of methylation in promoter inactivation, X-chromosome and duplicate sequence inactivation and in chromatin structure changes, are presented.

Inactivation of the maize transposable element Activator (Ac) is associated with its DNA modification.

The Activator (Ac) element at the waxy locus (wx-m7 allele) has the ability to undergo changes in its genetic activity and cycles between an active and inactive phase. Comparison of active Ac elements at several loci and the inactive Ac at wx-m7 by Southern blot analysis revealed that the inactive Ac sequence was not susceptible to digestion by the methylation sensitive enzyme PvuII while active elements were susceptible to PvuII digestion. Restriction digest comparisons between the clones of the active and inactive Ac elements were indistinguishable. Further analyses with the enzymes SstII and the methylation sensitive and insensitive isoschizomers EcoRII and BstNI showed the inactive Ac sequence was methylated at these sites, whereas the active Ac was hypomethylated. Although the active Ac at the wx-m7 allele in different genetic backgrounds showed differences in the Ac DNA modification pattern, at least a fraction of genomic DNA contained Ac sequences that were unmethylated at all of the internal sites we assayed. These data may suggest a role for DNA modification in the ability of Ac to transpose from the waxy locus and to destabilize unlinked Ds elements.