Kjell Stålberg

Seed-specific overexpression of an endogenous Arabidopsis phytoene synthase gene results in delayed germination and increased levels of carotenoids, chlorophyll, and abscisic acid.

Phytoene synthase catalyzes the dimerization of two molecules of geranylgeranyl pyrophosphate to phytoene and has been shown to be rate limiting for the synthesis of carotenoids. To elucidate if the capacity to produce phytoene is limiting also in the seed of Arabidopsis (Wassilewskija), a gene coding for an endogenous phytoene synthase was cloned and coupled to a seed-specific promoter, and the effects of the overexpression were examined. The resulting transgenic plants produced darker seeds, and extracts from the seed of five overexpressing plants had a 43-fold average increase of β-carotene and a total average amount of β-carotene of approximately 260 μg g–1 fresh weight. Lutein, violaxanthin, and chlorophyll were significantly increased, whereas the levels of zeaxanthin only increased by a factor 1.1. In addition, substantial levels of lycopene and α-carotene were produced in the seeds, whereas only trace amounts were found in the control plants. Seeds from the transgenic plants exhibited delayed germination, and the degree of delay was positively correlated with the increased levels of carotenoids. The abscisic acid levels followed the increase of the carotenoids, and plants having the highest carotenoid levels also had the highest abscisic acid content. Addition of gibberellic acid to the growth medium only partly restored germination of the transgenic seeds.

Disruption of an overlapping E-box/ABRE motif abolished high transcription of the napA storage-protein promoter in transgenic Brassica napus seeds

The storage protein napin is one of the major protein components of Brassica napus L. (oilseed rape) seeds. To investigate the transcriptional regulation of the napin promoter, different constructs of the napin gene napA promoter were fused to the Escherichia coli uidA gene and transformed into B. napus. A -152-bp promoter construct directed a strong expression of the marker gene in mature seeds. The 5′ deletion of an additional 8 completely abolished this activity. This deletion disrupted sequence motifs that are similar to an E-box, (CA↓ NNTG) and an ABRE (CGCCA↓CGTGTCC) element (identity is indicated by bold face). Further, internal deletion of a segment corresponding to -133 to -121 caused an eightfold reduction in the activity of the -152 construct. This region contains an element, CAAACAC, conserved in many storage-protein gene promoters. These results imply that the E-box/ABRE-like sequence is a major motif of the napA promoter and suggest that the CAAACAC sequence is important for high activity of the napA promoter. Similar results have been obtained by analysing some of the constructs in transgenic tobacco, suggesting that many of the cis-elements in the napA promoter are conserved, at least in dicotyledonous species.

Functional dissection of a napin gene promoter: identification of promoter elements required for embryo and endosperm-specific transcription

The promoter region (−309 to +44) of the Brassica napus storage protein gene napA was studied in transgenic tobacco by successive 5′ as well as internal deletions fused to the reporter gene GUS (β-glucuronidase). The expression in the two main tissues of the seed, the endosperm and the embryo, was shown to be differentially regulated. This tissue-specific regulation within the seed was found to affect the developmental expression during seed development. The region between −309 to −152, which has a large effect on quantitative expression, was shown to harbour four elements regulating embryo and one regulating endosperm expression. This region also displayed enhancer activity. Deletion of eight bp from position −152 to position −144 totally abolished the activity of the napA promoter. This deletion disrupted a cis element with similarity to an ABA-responsive element (ABRE) overlapping with an E-box, demonstrating its crucial importance for quantitative expression. An internal deletion of the region −133 to −120, resulted in increased activity in both leaves and endosperm and a decreased activity in the embryo. Within this region, a cis element similar to the (CA)n element, found in other storage protein promoters, was identified. This suggest that the (CA)n element is important for conferring seed specificity by serving both as an activator and a repressor element.

Deletion analysis of a 2S seed storage protein promoter of Brassica napus in transgenic tobacco

The promoter and upstream region of the Brassica napus 2S storage protein napA gene were studied to identify cis-acting sequences involved in developmental seed-specific expression. Fragments generated by successive deletions of the 5′ control region of the napA gene were fused to the reporter gene β-glucuronidase (GUS). These constructs were used to transform tobacco leaf discs. Analyses of GUS activities in mature seeds from the transformed plants indicated that there were both negatively and positively acting sequences in the napin gene promoter. Deletion of sequences between −1101 and −309 resulted in increased GUS activity. In contrast, deletion of sequences between −309 and −211 decreased the expression. The minimum sequence required for seed-specific expression was a 196 bp fragment between −152 and +44. Further 5′ deletion of the fragment to −126 abolished this activity. Sequence comparison showed that a G box-like sequence and two sequence motifs conserved between 2S storage protein genes are located between −148 to −120. Histochemical and fluorometric analysis of tobacco seeds showed that the spatial and developmental expression pattern was retained in the deletion fragments down to −152. However, the expression in tobacco seeds differed from the spatial and temporal expression in B. napus. In tobacco, the napA promoter directed GUS activity early in the endosperm before any visible activity could be seen in the heart-shaped embryo. Later, during the transition from heart to torpedo stages, the main expression of GUS was localized to the embryo. No significant GUS activity was found in either root or leaf.

A family of eukaryotic lysophospholipid acyltransferases with broad specificity.

The budding yeast ALE1 gene encodes a lysophospholipid acyltransferase (LPLAT) with broad specificity. We show that yeast LPLAT (ScLPLAT) belongs to a distinct protein family that includes human MBOAT1, MBOAT2, MBOAT4, and several closely related proteins from other eukaryotes. We further show that two plant proteins within this family, the Arabidopsis proteins AtLPLAT1 and AtLPLAT2, possess lysophospholipid acyltransferase activities similar to ScLPLAT. We propose that other members of this protein family, which we refer to as the LPLAT family, also are likely to possess LPLAT activity. Finally, we show that ScLPLAT differs from the specific lysophosphatidic acid acyltransferase that is encoded by SLC1 in that it cannot efficiently use lysophosphatidic acid produced by acylation of glycerol‐3‐phosphate in vitro.

Characterization of two Arabidopsis thaliana acyltransferases with preference for lysophosphatidylethanolamine

BackgroundTwo previously uncharacterized Arabidopsis genes that encode proteins with acyltransferase PlsC regions were selected for study based on their sequence similarity to a recently identified lung lysophosphatidylcholine acyltransferase (LPCAT). To identify their substrate specificity and biochemical properties, the two Arabidopsis acyltransferases, designated AtLPEAT1, (At1g80950), and AtLPEAT2 (At2g45670) were expressed in yeast knockout lines ale1 and slc1 that are deficient in microsomal lysophosphatidyl acyltransferase activities.ResultsExpression of AtLPEAT1 in the yeast knockout ale1 background exhibited strong acylation activity of lysophosphatidylethanolamine (LPE) and lysophosphatidate (LPA) with lower activity on lysophosphatidylcholine (LPC) and lysophosphatidylserine (LPS). AtLPEAT2 had specificities in the order of LPE > LPC > LPS and had no or very low activity with LPA. Both acyltransferases preferred 18:1-LPE over 16:0-LPE as acceptor and preferred palmitoyl-CoA as acyl donor in combination with 18:1-LPE. Both acyltransferases showed no or minor responses to Ca2+, despite the presence of a calcium binding EF-hand region in AtLPEAT2. AtLPEAT1 was more active at basic pH while AtLPEAT2 was equally active between pH 6.0 – 9.0.ConclusionThis study represents the first description of plant acyltransferases with a preference for LPE. In conclusion it is suggested that the two AtLPEATs, with their different biochemical and expression properties, have different roles in membrane metabolism/homoeostasis.

Seed-specific regulation of the napin promoter in Brassica napus

Summary The expression of the 2S storage protein napin in Brassica napus is dependent upon ABI3. Mutation analyses identified a promoter segment between −152 to −120, denoted the B-box, to be critical for the activity of the promoter in transgenic tobacco seeds. The B-box, which is highly conserved in all 2S promoters and which displays similarity to abscisic acid response elements, binds at least two different nuclear protein complexes. Mutation of either of the two B-box elements binding nuclear protein complexes abolished the activity of the promoter in transgenic tobacco seeds. The concatemerised B-box in front of the minimal 35 S promoter from cauliflower mosaic virus, directed seed-specific transcription in transgenic tobacco and was able to induce transcription in young tobacco seedlings ectopically expressing ABI3. This implies that the B-box is one region through which ABI3 controls the napin promoter.