Transcription and somatic transposition of the maize En/Spm transposon system in rice.

Transposition of the maize En/Spm system in rice was investigated using a two-component construct consisting of an immobilised transposase source driven by the CaMV 35S-promoter, and a modified I/dSpm transposon. Mobilization of I/dSpm in somatic sectors was demonstrated by sequencing of excision products and isolation of flanking genomic sequences in T0 and T1 progeny plants. Since the transposition efficiency appeared to be considerably lower than that observed in maize or in other heterologous systems like Arabidopsis, we examined En/Spm transcription and splicing in the transgenic rice plants. Northern analysis revealed the presence of transcripts encoding the active TnpA and TnpD transposases, with the latter predominating; this is the reverse of what is seen in maize and Arabidopsis. RT-PCR analysis confirmed the occurrence of correct splicing and the formation of the two other alternatively spliced transcripts (TnpB and TnpC), as previously described for maize. Two alternative splice donor sites at the end of exon 1 were identified in maize at positions 578 and 704. We observe that rice is similar to maize in that TnpA is preferentially spliced at position 578. We also show that in Arabidopsis splicing occurs preferentially at position 704, as in other dicots like tobacco. These observations indicate differences in the splicing of transcripts of the maize En/Spm element between dicot and monocot hosts. Nevertheless, the ratio in which the transcripts for the active transposases are produced seems to determine the efficiency of transposition, irrespective of the host considered. A limiting amount of TnpA might therefore be responsible for the lower transposition activity of En/Spm in rice. Alternatively, reduced mobility of the modified I/dSpm element used may have resulted from the absence of critical sequences necessary for transposition. The influence of endogenous, autonomous, En/Spm -related elements present in the rice genome on the transposition behaviour of the exogenous maize element is also considered.

Early and multiple Ac transpositions in rice suitable for efficient insertional mutagenesis.

A GFP excision assay was developed to monitor the excision of Ac introduced into rice by Agrobacterium-mediated transformation. The presence of a strong double enhancer element of the CaMV 35S promoter adjacent to the Ac promoter induced very early excision, directly after transformation into the plant cell, exemplified by the absence of Ac in the T-DNA loci. Excision fingerprint analysis and characterization of transposition events from related regenerants revealed an inverse correlation between the number of excision events and transposed Ac copies, with single early excisions after transformation generating Ac amplification. New transpositions were generated at a frequency of 15-50% in different lines, yielding genotypes bearing multiple insertions, many of which were inherited in the progeny. The sequence of DNA flanking Ac in three representative lines provided a database of insertion tagged sites suitable for the identification of mutants of sequenced genes that can be examined for phenotypes in a reverse genetics strategy to elucidate gene function. Remarkably, two-thirds of Ac tagged sites showing homology to sequences in public databases were in predicted genes. A clear preference of transposon insertions in genes that are either predicted by protein coding capacity or by similarity to ESTs suggests that the efficiency of recovering knockout mutants of genes could be about three times higher than random. Linked Ac transposition, suitable for targeted tagging, was documented by segregation analysis of a crippled Ac element and by recovery of a set of six insertions in a contiguous sequence of 70 kb from chromosome 6 of rice.

Transcriptional repression by Oshox1, a novel homeodomain leucine zipper protein from rice.

This paper describes the characterization of Oshox1, a cDNA clone from rice encoding a member of the homeodomain-leucine zipper (HD-Zip) class of putative transcription factors. Oshox1 maps to chromosome 10 and belongs to a family of related rice genes. Two-hybrid assays showed that Oshox1 protein can homodimerize, but can also form heterodimers with an Arabidopsis HD-Zip protein. This suggests that protein-protein interactions may also occur between different HD-Zip proteins in rice, which would provide enormous versatility for generating specific gene-control mechanisms. Oshox1 mRNA could be detected in various rice tissues at different developmental stages, with highest levels in embryos, shoots of seedlings, and leaves of mature plants. Transgenic expression of Oshox1 in Arabidopsis retarded growth and affected leaf size and shape, indicative of a role as developmental regulator. In vitro and in vivo DNA-binding studies revealed that Oshox1 interacts with the pseudopalindromic sequence CAAT(C/G)ATTG, confirming that the protein represents a transcription factor. Oshox1 was found to repress reporter gene activity in rice suspension cells, most likely by a mechanism of active transcriptional repression. Repression was strictly dependent on the presence of upstream Oshox1 binding sites in the reporter gene constructs and a function of the N-terminal region of Oshox1, preceding the homeodomain.