Contrasting genome organisation: two regions of the Brassica oleracea genome compared with collinear regions of the Arabidopsis thaliana genome.

Brassica crop species are of worldwide importance and are closely related to the model plant Arabidopsis thaliana for which the complete genome sequence has recently been established. We investigated collinearity of marker order by comparing two contrasting regions of the Brassica oleracea genome with homologous regions of A. thaliana. Although there is widespread replication of marker loci in both A. thaliana and B. oleracea, we found that a combination of genetic markers mapped in B. oleracea, including RFLPs, CAPS, and SSRs allowed comparison and interpretation of medium-scale chromosomal organisation and rearrangements. The interpretation of data was facilitated by hybridising probes onto the whole A. thaliana genome, as represented by BAC contigs. Twenty marker loci were sampled from the whole length of the shortest B. oleracea linkage group, 06, and 21 from a 30.4-cM section of the longest linkage group, 03. There is evidence of locus duplication on linkage group 06. Locus order is well conserved between a putative duplicated region of 10.5 cM and a discrete region comprising 25 cM of A. thaliana chromosome I. This was supported by evidence from seven paralogous loci, three of which were duplicated in a 30.6-cM region of linkage group 06. The pattern of locus order for the remainder of linkage group 06 and the sampled section of linkage group 03 was more complex when compared with the A. thaliana genome. Although there was some conservation of locus order between markers on linkage group 03 and approximately 9 cM of A. thaliana chromosome I, this was superimposed upon a complex pattern of additional loci that were replicated in both A. thaliana and B. oleracea. The results are discussed in the context of the ability to use collinear information to assist map-based cloning.

The GATA-binding protein CGF-1 is closely related to GT-1.

Many light-regulated genes contain a conserved GATA motif in their 5'-upstream region. We have characterized in detail the GATA-binding factor, CGF-1, which bonds within a 73 bp TATA-proximal light/circadian regulatory element in the Arabidopsis cab2 promoter and to two more sites farther upstream. CGF-1 was found to be distinct from other metal-dependent GATA-binding factors, but to have the same sequence requirements for binding and similar physical and chemical properties as GT-1, a factor required for light regulation of the tobacco rbcS-3A gene. CGF-1 was found to be constitutively present in extracts and was shown to be immunologically related to GT-1. The close similarity between CGF-1 and GT-1 suggests that a GT-1-like factor is involved in the phytochrome/circadian regulation of the cab2 gene. CGF-1 and GT-1 were also found to have similar sequence specificities to another constitutively-regulated GATA factor, IBF-2b, which binds the I box region of the tomato nitrate reductase gene. Of three complexes detected using an IBF-2b-specific probe, only one was identical to CGF-1/GT-1. The other two were similar to IBF-2b, demonstrating that CGF-1/GT-1, although very similar, are actually distinct from IBF-2b. These data indicate that more than one factor can bind to the same short sequence and may indicate how constitutively present factors like GT-1 can play a role in light regulation.

Circadian clock- and phytochrome-regulated transcription is conferred by a 78 bp cis-acting domain of the Arabidopsis CAB2 promoter.

The Arabidopsis CAB2 promoter was used to define the terminal genomic targets that are subject to regulation by the circadian clock. An in vivo cab::luciferase bioluminescent marker was used to enable the assaying of the expression of chimeric constructs with unprecedented sensitivity and time resolution in living seedlings. Dissection of -322 to +1 of the CAB2 promoter has revealed several interesting features: it was demonstrated that the 323 bp fragment contains at least one strong general positive element. The positive element contains an ACGT core sequence specifically bound by a protein activity, termed CUF-1, and contributes to high level expression but is not required for phytochrome- or circadian-regulation. Moreover, a 78 bp domain was defined that confers both circadian- and phytochrome-regulation upon heterologous promoters. Conserved GATA sequences within the 78 bp regulatory domain are specifically bound by a protein factor designated CGF-1. The binding specificity of CGF-1 appears to be related to the GT-family of trihelix DNA-binding proteins. The role of these DNA-protein interactions is discussed in terms of clock- and phytochrome regulation, and their relevance as targets for pathways defined by photomorphogenic mutants.

Cloning, characterization and import studies on protochlorophyllide reductase from wheat (Triticum aestivum).

A full-length protochlorophyllide reductase clone (pWR5) has been isolated from a dark-grown wheat (Triticum aestivum) cDNA library generated in the phage vector lambda gt10. Comparison of the sequence of pWR5 with published sequences indicates a high degree of conservation of the structure of the mature protein amongst species but with the structure of the transit peptide less highly conserved. Within the cereals, the structure of the complete preprotein shows a remarkable degree of sequence homology (98% between barley and wheat). In vitro expression of pWR5 generates a preprotein of the expected molecular mass, approx. 41 kDa. Isolated pea chloroplasts can import, process and locate the mature reductase to the thylakoid membranes. From analysis of the CNBr-cleavage fragments of the N-[3H]phenylmaleimide-treated enzyme, the substrate-protected cysteine group in the enzyme is tentatively identified as Cys-296.

Cloning and sequencing of protochlorophyllide reductase.

Putative protochlorophyllide reductase cDNA clones (252 and 113) were isolated from an etiolated-oat (Avena sativa) cDNA library. These were used to indirectly characterize a further clone, p127, isolated from a lambda-phage gt11 cDNA library. The latter (1.15 kb in length) was sequenced, and the derived amino acid sequence was shown to be remarkably similar to that derived from chemical analysis of a CNBr-cleavage fragment of the purified reductase, p127 codes for more than 95% of the reductase protein.