A novel hybrid open reading frame formed by multiple cellular gene transductions by a plant long terminal repeat retroelement.

The discovery that vertebrate retroviruses could transduce cellular sequences was central to cancer etiology and research. Although not well documented, transduction of cellular sequences by retroelements has been suggested to modify cellular functions. The maize Bs1 transposon was the first non-vertebrate retroelement reported to have transduced a portion of a cellular gene (c-pma). We show that Bs1 has, in addition, transduced portions of at least two more maize cellular genes, namely for 1,3-beta-glucanase (c-bg) and 1,4-beta-xylan endohydrolase (c-xe). We also show that Bs1 has maintained a truncated gag domain with similarity to the magellan gypsy-like long terminal repeat retrotransposon and a region that may correspond to an env-like domain. Our findings suggest that, like oncogenic retroviruses, the three transduced gene fragments and the Bs1 gag domain encode a fusion protein that has the potential to be expressed. We suggest that transduction by retroelements may facilitate the formation of novel hybrid genes in plants.

Molecular characterization of the Abp1 5'-flanking region in maize and the teosintes.

Auxin-binding protein 1 subsp. mays (ABP1) has been suggested as a receptor mediating auxin-induced cell expansion and differentiation. In maize (Zea mays), ABP1 is encoded by a single gene, Abp1. The TATA and CAAT promoter elements as well as the transcriptional start site were previously identified and all were found to be located within a transposable element (TE), Tourist-Zm11. In this study we report the cloning and characterization of the Abp1 5'-flanking region in maize and its wild relatives, the teosintes. We provide evidence for insertion polymorphism corresponding to Tourist-Zm11 and two novel TEs, Batuta and Pilgrim. Despite this polymorphic structure, the Abp1 core promoter in maize and the teosintes is conserved, is located downstream of the TE insertions in the 5'-flanking region, and is TATA-less. We discuss the potential evolutionary impact of these TEs on the regulation of Abp1 gene expression.

An open reading frame for a protein involved in cytochrome c biogenesis is split into two parts in Brassica mitochondria.

A plant mitochondrial gene with sequence similarity to ccl1, a bacterial gene involved in cytochrome c biogenesis, occurs as a single open reading frame in wheat, Oenothera, carrot and Marchantia mtDNAs. In Brassica napus "Polima" or Brassica campestris mtDNA, however, this open reading frame is split into two segments that are located 60 kb apart on the master-circle form of the genome. Although transcripts of the split ORF are edited in a manner similar to that of a functional gene, transcripts that span both portions of the ORF are not evident in gel-blot hybridization experiments. Low-abundance transcripts that span both portions of the split ORF can be detected by RT-PCR, but these contain an additional 54-bp sequence, inserted between the two segments, that is unrelated to the corresponding sequences of other plants. Since this additional sequence introduces an in-frame stop codon, no transcripts have been found that could be translated to yield a protein product of a size similar to that present in other plant species. An antiserum directed against the product of the corresponding wheat gene detects polypeptides of similar size in wheat and Brassica mitochondria. This antiserum, however, immunoprecipitates a labelled polypeptide from the products of wheat, but not Brassica, in organello protein synthesis. Gel-blot analysis of total Brassica DNA indicates that sequences capable of hybridizing with the ORF are present in the nuclear genome. We suggest that the functional form of the Brassica gene may reside in the nucleus.