Nucleotide sequence and regulated expression of a wound-inducible potato gene (wun1)

Summary Mechanical wounding of potato leaves, stems, roots and tubers leads to a rapid increase of wun1 mRNA. In potato leaves, the wound-induced accumulation of wun1 mRNA is inhibited by the addition of sucrose or other osmotically active agents. This inhibition is organ specific since sucrose does not prevent wun1 mRNA accumulation in wounded tubers. In contrast, expression of patatin was shown to be repressed in tubers by wounding and this repression was reversed by increasing osmotic pressure. Sequence data obtained from the analysis of a wun1 cDNA and a wun1 genomic clone show no homology to any gene known so far. Histochemical data demonstrate a striking analogy in cell specific expression of chimeric genes expressed under the control of the wun1 promoter and the cell specific production of callose in wounded tobacco leaves.     

Potato granule-bound starch synthase promoter-controlled GUS expression: regulation of expression after transient and stable transformation

Chimaeric genes of promoter sequences from the potato gene encoding granule-bound starch synthase (GBSS) and the -glucuronidase (GUS) reporter gene were used to study GBSS expression and regulation. Analysis of stable transformants revealed that a GBSS promoter sequence of 0.4 kb was sufficient to result in tissue-dependent GUS expression: levels in stably transformed microtubers exceeded levels in corresponding leaves by orders of magnitude. GBSS-GUS constructs could be transiently expressed in leaf protoplasts from wild-type and amylose-free potato lines, etuberosumSolanum brevidens, Nicotiana tabacum andArabidopsis thaliana. Transient expression levels in potato leaf protoplasts were clearly lower than in corresponding suspension cell protoplasts. This lower expression in leaf protoplasts could not be elevated by increasing DNA concentrations during transfection. Light incubation of electroporated suspension cell protoplasts reduced transient GBSS-GUS expression, whereas incubation of transfected protoplasts in media with different sucrose concentrations did not affect transient expression levels. However, electroporated protoplasts, isolated from suspensions, which had been grown on media with increasing amounts of sucrose showed a sucrose concentration-dependent transient expression profile. This indicates that studying GBSS regulation by transient expression experiments needs pre-treatment of the protoplast source. Sequence data of the GBSS promoter were compared to those of two other potato alleles.     

Transient gene expression in electroporated Solanum protoplasts

Electroporation was used to evaluate parameters important in transient gene expression in potato protoplasts. The protoplasts were from leaves of wild potato Solanum brevidens, and from leaves, tubers and suspension cells of cultivated Solanum tuberosum cv. Désirée. Reporter enzyme activity, chloramphenicol acetyl transferase (CAT) under the control of the cauliflower mosaic virus (CaMV) 35S promoter, depended on the field strength and the pulse duration used for electroporation. Using field pulses of 85 ms duration, the optimum field strengths for maximum CAT activity were: S. brevidens mesophyll protoplasts –250 V/cm; Désirée mesophyll protoplasts –225 V/cm; Désirée suspension culture protoplasts –225 V/cm; and Désirée tuber protoplasts –150 V/cm. The optimum field strengths correlated inversely with the size of the protoplasts electroporated; this is consistent with biophysical theory. In time courses, maximum CAT activity (in Désirée mesophyll protoplasts) occurred 36–48 h after electroporation. Examination at optimised conditions of a chimaeric gene consisting of a class II patatin promoter linked to the -glucuronidase (gus) gene, showed expression (at DNA concentrations between 0–10 pmol/ml) comparable to the CaMV 35S promoter in both tuber and mesophyll protoplasts. At higher DNA concentrations (20–30 pmol/ml) the patatin promoter directed 4–5 times higher levels of gus expression. Implications and potential contributions towards studying gene expression, in particular of homologous genes in potato, are discussed.     

Both wound-inducible and tuber-specific expression are mediated by the promoter of a single member of the potato proteinase inhibitor II gene family

A chimeric gene consisting of 1.3 kb of the 5' regulatory region of a member of the potato proteinase inhibitor II gene family, the coding region of the bacterial β-glucuronidase (GUS) gene and 260 bp of the proteinase inhibitor II 3'-untranslated region containing the poly(A) addition site was introduced into potato and tobacco by Agrobacterium tumefaciens mediated transformation. Analysis of transgenic plants demonstrates systemic, wound-inducible expression of this gene in stem and leaves of potato and tobacco. Constitutive expression was found in stolons and tubers of non-wounded potato plants. Histochemical experiments based on the enzymatic activity of the GUS protein indicate an association of the proteinase inhibitor II promoter activity with vascular tissue in wounded as well as in systemically induced non-wounded leaves, petioles, potato stems and in developing tubers. These data prove that one single member of the proteinase inhibitor II gene family contains cis-active elements, which are able to respond to both developmental and environmental signals. Furthermore they support the hypothesis of an inducing signal (previously called proteinase inhibitor inducing factor), which is released at the wound site and subsequently transported to non-wounded parts of the plant via the vascular system from where it is released to the surrounding tissue.     

Comparisons of the efficiency of some promoters in silver birch (Betula pendula)

The efficiency of several promoters (pin2 from potato, ubiquitin from sunflower, rolC from Agrobacterium rhizogenes, act1 from rice and CaMV 35S from cauliflower mosaic virus) fused to the uidA reporter gene was measured after biolistic bombardment of birch leaves (Betula pendula L.). The highest level of β-glucuronidase (GUS) activity was achieved with the pin2 promoter and the lowest activity with the CaMV 35S promoter. The activity of the potato wound-inducible promoter (pin2) was also tested in stably transformed birch. The promoter showed induced activity after mechanical wounding and feeding by leaf weevils. The systemic effect was confirmed by enhanced GUS activity in non-wounded leaves. The results of this study indicated that the potato wound-inducible promoter maintains its function in birch and would be a suitable promoter in studies of insect-birch interaction at the molecular level. Received: 17 October 1996 / Revision received: 7 February 1997 / Accepted: 1 March 1997     

Use of the human elongation factor 1 alpha promoter as a versatile and efficient expression system

We have characterized the promoter region of the human elongation factor 1 alpha-encoding gene (EF-1 alpha) and developed a versatile expression system which has a wide host range and a high efficiency of gene expression. To identify the promoter region of the EF-1 alpha gene necessary for efficient gene expression, we constructed four pEF-CAT plasmids that have the bacterial cat gene fused to four different sites of the human EF-1 alpha gene: (i) ligated to the end of the TATA box (pEF220-CAT); (ii) ligated in exon 1 (pEF204-CAT and pEF233-CAT), and (iii) ligated in exon 2 (pEF321-CAT). All the pEF-CAT plasmids were highly expressed in all the cell types tested, including fibroblasts and lymphoid cells. Plasmid pEF321-CAT, which contains the first exon and the first intron, gave the highest level of cat expression. Plasmids pEF204- and pEF233-CAT, which contain part of the first exon but do not contain the first intron, were less efficient in cat expression than was pEF321-CAT. Plasmid pEF220-CAT, which lacks both the first exon and the first intron, was the least efficient. Plasmid pEF321-CAT was several- to 100-fold more efficient in cat expression than plasmid pSV2-CAT depending on the recipient cell types. The promoter of pEF321 plasmid also directed the stable expression of the bacterial neo gene more efficiently than the promoter of the simian virus 40 (SV40) early gene or the long terminal repeat of Rous sarcoma virus. Using this system, the SV40 early gene and the cDNA encoding human CD4 were also expressed efficiently.     

Nucleotide sequence of proteinase inhibitor II encoding cDNA of potato (Solanum tuberosum) and its mode of expression

Summary Two cDNA clones containing the complete coding region of a developmentally controlled (tuber-specific) as well as environmentally inducible (wound-inducible) gene from potato (Solanum tuberosum) have been sequenced. The open reading frame codes for 154 amino acids. Its sequence is highly homologous to the proteinase inhibitor II from tomato, indicating that the cDNA's encode the corresponding proteinase inhibitor II of potato. In addition the putative potato proteinase inhibitor II contains a sequence which is completely homologous with that of another small peptide proteinase inhibitor from potato, called PCI-I. Evidence is presented that this small peptide is probably derived from the proteinase inhibitor II by posttranslational processing.Northern type experiments using RNA from wounded and nonwounded leaves demonstrate that RNA homologous to the putative proteinase inhibitor II cDNA's accumulates in leaves as a consequence of wounding, whereas normally the expression of this gene is under strict developmental control, since it is detected only in tubers of potato (Rosahl et al. 1986). In addition the induction of this gene in leaves can also be achieved by the addition of different polysaccharides such as poly galacturonic acid or chitosan. In contrast to the induction of its expression by wounding in leaves, wounding of tubers results in a disappearance of the proteinase II inhibitor m-RNA from these organs.     

Expression of recombinant Renilla luciferase in transgenic plants results in high levels of light emission

A 970 bp DNA fragment which encodes the luciferase enzyme of the marine soft coral Renilla reniformis was fused to the cauliflower mosaic virus (CaMV) promoter. The construct pPCV702-ruc was transferred into alfalfa protoplasts by Ca-PEG-mediated transformation and into tobacco, tomato and potato plants by Agrobacterium -mediated transformation. The light emission from homogenates of alfalfa protoplasts transformed with pPCV702-ruc was 16-fold higher than that of protoplasts transformed with the same vector carrying the bacterial luxF gene. Application of a 3 µM aequous solution of 2-benzyl luciferin (luciferin) on to calli, leaves, roots and slices of tomato fruits and potato tubers of transformed plants resulted in strong light emission within seconds which could be easily visualized by a photon counting camera. Light emissions obtained from tissue homogenates of tobacco plants containing a single copy of the pPCV702-ruc construct were around 20-fold higher than those from plants carrying multiple copies of the firefly luciferase gene and around 360-fold higher than those from plants transformed with the bacterial luciferase gene. Owing to its high efficiency the Renilla luciferase may become a useful and novel tool for gene expression studies in plants and other systems.     

Protoplast isolation and transient gene expression in switchgrass, Panicum virgatum L

Transient assay systems using protoplasts have been utilized in several plant species and are a powerful tool for rapid functional gene analysis and biochemical manipulations. A protoplast system has not been used in switchgrass (Panicum virgatum L.), even though it is a bioenergy crop that has received considerable attention. Here we report the first protocol to isolate large numbers of viable protoplasts from both leaves and roots of two switchgrass genotypes. Furthermore, we demonstrate transient expression of PEG-mediated DNA uptake in the isolated protoplasts by measuring the activity of beta-glucuronidase (GUS) reporter gene driven by either the Cauliflower mosaic virus (CaMV) 35S promoter or the maize ubiquitin 1 promoter. Protoplast transformation with either the 35S or the ubiquitin promoter resulted in an increase in GUS activity compared to the untransformed controls; however, the extent of GUS activity was considerably higher for the ubiquitin promoter than for the 35S promoter. Collectively, our results indicate an efficient protoplast isolation and transient assay system that can be used to facilitate gene expression studies in switchgrass.     

Abscisic acid and jasmonic acid activate wound-inducible genes in potato through separate, organ-specific signal transduction pathways

Mechanical damage to leaf tissue causes an increase in abscisic acid (ABA) which in turn activates the biosynthesis of jasmonic acid (JA). The resulting higher endogenous JA levels subsequently activate the expression of wound-inducible genes. This study shows that JA induces the expression of different sets of genes in roots and leaves of potato plants. When roots of intact plants were treated with JA, high levels of proteinase inhibitor II (pin2), cathepsin D inhibitor, leucine aminopeptidase and threonine deaminase mRNAs accumulated in the systemic leaves. However, in the treated roots, very low, if any, expression of these genes could be detected. In contrast, a novel, root-specific pin2 homologue accumulated in the JA-treated root tissue which could not be detected in leaves, either systemic or those directly treated with JA. Application of okadaic acid and staurosporine revealed that a protein phosphorylation step is involved in the regulation of this differential response. In leaves, a protein phosphatase is required for the JA-induced expression of pin2 and the other genes analysed. This phosphatase activity is not necessary for the JA-induced expression of a pin2 homologue in roots, suggesting the existence of different transduction pathways for the JA signal in these organs. The requirement of a protein phosphatase activity for JA-mediated gene induction has enabled identification of a JA-independent pathway for ABA induction of pin2 and the other wound-inducible genes. This alternative pathway involves a protein kinase, and appears to be selective for wound-inducible genes. Our data suggest the presence of a complex, organ-specific transduction network for regulating the effects of the plant hormones ABA and JA on gene expression upon wounding.     

Potato virus X as a vector for gene expression in plants

The suitability of potato virus X (PVX) as a gene vector in plants was tested by analysis of two viral constructs. In the first, the GUS gene of Escherichia coli was substituted for the viral coat protein gene. In the second, GUS was added into the viral genome coupled to a duplicated copy of the viral promoter for the coat protein mRNA. The viral construct with the substituted coat protein gene accumulated poorly in inoculated protoplasts and failed to spread from the site of infection in plants. These results suggest a role for the viral coat protein in key stages of the viral infection cycle and show that gene replacement constructs are not suitable for the production of PVX-based gene vector. The construct with GUS coupled to the duplicated promoter for coat protein mRNA also accumulated less well in protoplasts than the unmodified PVX, but did infect systemically and directed high level synthesis of GUS in inoculated and systemically infected tissue. Although there was some genome instability in the PVX construct, much of the viral RNA in the systemically infected tissue had retained the foreign gene insertion, especially in infected Nicotiana clevelandii plants. These data point to a general utility of PVX as a vector for unregulated gene expression in plants.     

Systemic induction of a potato pin2 promoter by wounding,methyl iasmonate,and abscisic acid in transgenic rice plants

To address the question whether common signal(s) and transduction pathways are used to mediate a systemic wound response in monocot and dicot plants, a fusion of the potato proteinase inhibitor II gene (pin2) promoter and the bacterial -glucuronidase gene (Gus)-coding region was introduced into rice. In transgenic rice plants, the expression of the pin2-Gus fusion gene displays a systemic wound response, although the expression level is relatively low. Incorporation of the first intron from the rice actin 1 gene (Act1) into the 5-untranslated region of the pin2-Gus construct results in high-level, systemically wound-inducible expression of the modified construct in transgenic rice plants. Histochemical analysis shows that this high-level, wound-inducible expression is associated with the vascular tissue in both leaves and roots. Furthermore, the expression of the pin2-Act1 intron-Gus fusion gene in transgenic rice plants can be systemically induced by both methyl jasmonate (MJ) and the phytohormone abscisic acid (ABA). These results suggest that the signal(s) mediating the observed systemic wound response and certain steps of the transduction pathways are conserved between dicot and monocot plants. Transient expression assays show that the pin2-Act1 intron-Gus construct is also actively expressed in transformed cells and tissues of several other monocot plants. Thus, the wound-inducible pin2 promoter in combination with the rice Act1 intron 1 might be used as an efficient regulator for foreign gene expression in transgenic monocot plants.