Evolution of anthocyanin biosynthesis in maize kernels: the role of regulatory and enzymatic loci.

Understanding which genes contribute to evolutionary change and the nature of the alterations in them are fundamental challenges in evolution. We analyzed regulatory and enzymatic genes in the maize anthocyanin pathway as related to the evolution of anthocyanin-pigmented kernels in maize from colorless kernels of its progenitor, teosinte. Genetic tests indicate that teosinte possesses functional alleles at all enzymatic loci. At two regulatory loci, most teosintes possess alleles that encode functional proteins, but ones that are not expressed during kernel development and not capable of activating anthocyanin biosynthesis there. We investigated nucleotide polymorphism at one of the regulatory loci, cl. Several observations suggest that cl has not evolved in a strictly neutral manner, including an exceptionally low level of polymorphism and a biased representation of haplotypes in maize. Curiously, sequence data show that most of our teosinte samples possess a promoter element necessary for the activation of the anthocyanin pathway during kernel development, although genetic tests indicate that teosinte cl alleles are not active during kernel development. Our analyses suggest that the evolution of the purple kernels resulted from changes in cis regulatory elements at regulatory loci and not changes in either regulatory protein function nor the enzymatic loci.

Distribution of Bs1 retrotransposons in Zea and related genera.

Thirty-eight accessions from Zea and 20 accessions from related genera were probed for the presence of Bs1, a retrotransposon originally found in maize. All maize and teosinte plants tested show the presence of Bs1 in one to five densely hybridizing bands. The mean copy numbers of Bs1 elements among the maize and teosinte accessions were similar: 2.92 and 3.25, respectively, with no large differences between any subgroups. Most exotic maize samples exhibited two common bands of 7.8 kb and 4.7 kb. Section Zea teosintes (but not teosintes of section Luxuriantes) also show the presence of a common band of the same size as the smaller common band in maize. At reduced stringency, Tripsacum dactyloides exhibited a single hybridizing band at 6.9 kb. Results argue for the evolution of maize from a mexicana or parviglumis teosinte, and the evolution of the Bs1 element within the tribe Andropogoneae. Additionally, recombinant inbred lines were probed for the presence of Bs1, in order to map the chromosomal locations of Bs1 elements in four different maize lines. Two of the recombinant inbred parental lines had an element (Bs1-F) on chromosome 5, while the other two lines had an element (Bs1-S) on chromosome 8. Restriction site polymorphisms have apparently arisen in the vicinity of Bs1-S since its insertion. Segregation analysis of other lines was also performed; the data indicate that Bs1 has the distribution expected of a transposable element, different locations in different lines, and not that of a fixed gene locus. However, the common bands in the Zea mays lines and the recombinant inbred data imply that Bs1 is not highly mobile.

An unusually compact retrotransposon in maize.

Unlike any other known plant transposon, the maize transposable element Bs1 is similar to the retrotransposons previously described in yeast and Drosophila. Bs1 is bounded by 302 bp identical long terminal repeats (LTRs), and it contains open reading frames with apparent amino acid sequence similarity to reverse transcriptase and other retroviral pol gene enzymes. Bs1 is 3203 bp long, very short for a retrotransposon, and the apparent organization of its genetic information is significantly different from any previously described element. Although transcription of Bs1 has not been observed, it is probably an active transposon, since it was observed to transpose in a maize line that contains only two sequences hybridizing to Bs1 probes. Both of these sequences share 35 restriction sites with the cloned Bs1 element, and thus must be very similar or identical with it.