Analysis of a dehiscence zone endo-polygalacturonase in oilseed rape (Brassica napus) and Arabidopsis thaliana: evidence for roles in cell separation in dehiscence and abscission zones, and in stylar tissues during pollen tube growth.

The oilseed rape (Brassica napus) endo-polygalacturonase (endo-PG) RDPG1 is involved in middle lamella breakdown during silique opening. We investigated tissue-specific expression of RDPG1 in transgenic Arabidopsis thaliana. Cellular localization of endo-PG protein in Arabidopsis siliques was determined by immuno-electron microscopy. An Arabidopsis orthologue, ADPG1, was isolated and aligned with the sequence of RDPG1. The proximal 5' sequences as well as introns are largely conserved. Analysis of the histological GUS-staining pattern of two RDPG1 promoter-GUS (beta-glucuronidase) constructs in transgenic Arabidopsis revealed that the conserved proximal part of the 5'-flanking region directs expression in dehiscence zones of siliques and anthers, floral abscission zones and stylar tissues during pollen tube growth, branch points between stems and pedicel and expression associated with the apical meristem of seedlings, while the distal part of the RDPG1 5'-flanking region contains elements involved in vascular-associated expression in petals, cotyledons and roots. Subsequent RT-PCR analysis, on RNA from the corresponding rape tissues, confirms the staining pattern revealed in transgenic Arabidopsis, thereby justifying the use of Arabidopsis as a reliable model system for analysis of oilseed rape regulatory sequences.

Pectin engineering: modification of potato pectin by in vivo expression of an endo-1,4-beta-D-galactanase.

Potato tuber pectin is rich in galactan (oligomer of beta-1,4-linked galactosyl residues). We have expressed a fungal endo-galactanase cDNA in potato under control of the granule bound starch synthase promoter to obtain expression of the enzyme in tubers during growth. The transgenic plants displayed no altered phenotype compared with the wild type. Fungal endo-galactanase activity was quantified in the transgenic tubers, and its expression was verified by Western blot analysis. The effect of the endo-galactanase activity on potato tuber pectin was studied by Fourier transform infrared microspectroscopy, immuno-gold labeling, and sugar analysis. All analyses revealed alterations in pectin composition. Monosaccharide composition of total cell walls and isolated rhamnogalacturonan I fragments showed a reduction in galactosyl content to 30% in the transformants compared with the wild type. Increased solubility of pectin from transgenic cell walls by endo-polygalacturonase/pectin methylesterase digestion points to other changes in wall architecture.

A surprising effect of extraction conditions on the mobility of some plant virus coat proteins in SDS-PAGE.

The coat protein from purified particles of pea seedborne mosaic potyvirus (PSbMV) moves in SDS-PAGE with an apparent molecular weight (M(r)) of 36 kDa. However, extracts of PSbMV infected plants prepared with SDS or urea contain PSbMV immunoreactive proteins with apparent M(r) 39 kDa as well as 36 kDa. The low mobility form may be generated from the apparent M(r) 36 kDa form by incubating purified PSbMV particles with healthy plant sap in the presence of denaturing agents. A similar effect is observed with bean yellow mosaic potyvirus, but not with three viruses outside the potyvirus group. Experiments suggest that a soluble plant enzyme is responsible for the conversion, which apparently takes place only in vitro under denaturing conditions. This phenomenon may lead to erroneous conclusions about the M(r) of some viral coat proteins. However, the conversion can be prevented by heat treatment of the plant tissue prior to extraction.

Detection of a 45 kD protein derived from the N terminus of the pea seedborne mosaic potyvirus polyprotein in vivo and in vitro.

A 45 kD protein (Pro1) derived from the N terminus of the pea seedborne mosaic potyvirus (PSbMV) polyprotein has been detected in extracts of infected pea plants and among in vitro translation products of PSbMV genomic RNA. The genomic region coding for the first 231 amino acids of the PSbMV polyprotein was cloned and expressed in Escherichia coli as a fusion protein with beta-galactosidase. A rabbit antiserum raised against the fusion protein recognized an approximately 45 kD protein in immunoblots of extracts of PSbMV-infected pea leaves that was not present in extracts of healthy leaves. The highest concentration of the 45 kD protein was found in extracts of young leaves, suggesting the protein may be rapidly degraded in vivo. After in vitro translation of PSbMV genomic RNA in a wheat germ extract, the antiserum immunoprecipitated a 45 kD polypeptide as well as some lower molecular weight translation products. On the other hand, an approximately 90 kD polypeptide was immunoprecipitated from in vitro translation products of genomic RNA in a rabbit reticulocyte lysate, corresponding to the combined molecular weights of Pro1 and the helper component predicted from genomic sequence data.

The 5' untranslated region from pea seedborne mosaic potyvirus RNA as a translational enhancer in pea and tobacco protoplasts.

We have exploited the transient expression of foreign genes introduced into plant protoplasts to investigate the effect of the pea seedborne mosaic potyvirus (PSbMV) 5' untranslated region (5'UTR) on the level of gene expression in pea and tobacco protoplasts. The plant viral 5'UTRs were found to increase translation significantly in comparison to a plasmid containing no 5'UTR of viral origin. The enhancement effect of the 5'UTRs of PSbMV and tobacco etch potyvirus (TEV) was found to be similar in pea and tobacco protoplasts, indicating a host-independent role of the potyviral 5'UTRs in enhancing gene expression. Translational enhancement of the two potyviral 5'UTRs was similar to that of the 5'UTR of tobacco mosaic virus (TMV). This observation makes it attractive to use potyviral 5'UTRs as general translational enhancers in future genetic transformations of plants.

The complete nucleotide sequence of pea seed-borne mosaic virus RNA.

The complete nucleotide sequence of the RNA genome of pea seed-borne mosaic virus (PSbMV) was determined from cloned cDNA and by direct sequencing of viral RNA. The PSbMV genomic sequence was determined to be 9924 nucleotides in length excluding the poly(A) tract. The RNA contained an open reading frame (ORF) of 9618 nucleotides with the potential to encode a polyprotein with a calculated Mr of 364000 (364K). The ORF was flanked by a 5' untranslated leader sequence of 143 nucleotides and a 3' untranslated region of 163 nucleotides. A comparison of the PSbMV polyprotein with the polyproteins of the potyviruses tobacco etch virus (TEV), tobacco vein mottling virus (TVMV), plum pox virus (PPV) and potato virus Y (PVY) showed that PSbMV had a similar genome organization. The polyproteins had a high level of amino acid identity except in the N-terminal region, which varied in both sequence and length. Putative proteolytic cleavage sites were identified in the polyprotein of PSbMV by comparison with those identified for other potyviruses. The cleavage site between the 6K protein and the 49K proteinase is proposed to occur at the C-terminal side of glutamic acid and not at the C-terminal side of glutamine as in other potyviruses. In addition to the five proteolytic cleavage sites for the 49K proteinase identified previously, a sixth putative cleavage site was identified internally in the 49K proteinase of PSbMV, as well as in the 49K proteinases of TEV, TVMV, PPV, PVY and soybean mosaic virus. Cleavage at this site in the 49K proteinases of TEV, TVMV and PPV would result in an N-terminal protein of 22K to 24K, which is similar in size to the size determined for their VPgs.

Nucleotide sequence of pea seed-borne mosaic potyvirus coat protein gene.

cDNA of pea seed-borne mosaic potyvirus (PSbMV) RNA was synthesized and cloned in E. coli. Four overlapping clones that cover the complete PSbMV genome, except the extreme 5' terminus, were identified by restriction enzyme mapping, hybridization analysis, and partial sequencing. Overlapping cDNA clones covering 1386 nucleotides of the 3' terminus were sequenced. The nucleotide sequence contains one open reading frame (ORF), followed by an untranslated region of 163 nucleotides and a poly(A)-tract. The deduced amino acid sequence was found to include the C-terminus of the predicted RNA-dependent RNA polymerase and the coat protein. A glutamine-alanine dipeptide was identified as a putative 49-kD proteinase cleavage site at the N-terminus of the coat protein.

In vivo expression of the 29000 Mr protein from RNA-2 of pea early browning tobravirus.

The purpose of this work has been to investigate in vivo transcription and translation products from an open reading frame (ORF) located downstream of the coat protein (CP) cistron on RNA-2 of pea early browning virus (PEBV). This work was initiated as a step towards elucidation of the significance of this putative gene. Sequence data on RNA-2 suggest that a 29,600 Mr (29.6K) protein is translated from the ORF in question. Hybridization with ORF-specific probes on Northern blots with RNA from infected plants showed that PEBV synthesizes a subgenomic RNA encoding CP (RNA-2a) with a size of 3000 nucleotides (nt) and that a putative subgenomic RNA (RNA-2b) encoding the 29.6K protein appears to have a size of 1600 nt. This is 300 nt less than the size predicted from the sequencing data. For antibody production, a cDNA fragment harbouring 85% of the 29.6K ORF was cloned into the pUEX3 expression vector. The resulting plasmid expresses the 29.6K protein as a fusion protein with beta-galactosidase and this protein was used for raising antiserum containing specific anti-29.6K protein antibodies. By using these antibodies on immunoblots it was demonstrated that the 29.6K protein is expressed in infected plants.