Lupine leghemoglobin I : expression in transgenic Lotus and tobacco tissues

The proximal parts of the promoters of the genes for symbiotic-type hemoglobins are generally conserved, but the promoter of the lbI gene of lupine (LulbI) shows some unusual structural features. It lacks typical organ-specific elements characteristic of all the leghemoglobin gene promoters described thus far. We have analysed its functional activity in transgenic Lotus corniculatus. A fusion construct between the lbI promoter and the GUS reporter gene was expressed mainly in the central zone of the root nodule, but the product was also detected in the non-nodule root zone and in roots in tissue culture. In roots of transgenic tobacco, the activity of the promoter was only 24% lower than in Lotus nodules. LulbI promoter activity was also detected in tobacco leaves. Lupine hemoglobin I has a higher sequence identity to symbiotic-type hemoglobins and thus it groups within the “Class II” hemoglobins.     

Stability of CaMV 35S-gus gene expression in (bird's foot trefoil) hairy root cultures under different growth conditions

Lotus corniculatus is an agronomically important forage legume. Genetic engineering offers opportunities both to improveL. corniculatus as a crop and to increase basic understanding of plant biochemistry and metabolism. Biosynthesis of secondary products and nitrogen fixation are two areas in which gene expression has been studied using hairy root cultures ofL. corniculatus. The stability of foreign gene expression in these cultures is critically important. TwoL. corniculatus root culture lines containing a reporter gene (CaMV 35S-gus) were used to investigate the stability of expression of a foreign gene under a range of conditions likely to be encountered in experiments. The hairy root culture lines were grown under varying conditions of light, temperature, nutrient supply, and in the presence of the auxin 2,4-D, or the elicitor glutathione. Expression of thegus gene, detected by measuring GUS activity, was found to be relatively stable under all of the conditions investigated.     

Lupine leghemoglobin I: expression in transgenic Lotus and tobacco tissues

The proximal parts of the promoters of the genes for symbiotic-type hemoglobins are generally conserved, but the promoter of the lbI gene of lupine (LulbI) shows some unusual structural features. It lacks typical organ-specific elements characteristic of all the leghemoglobin gene promoters described thus far. We have analysed its functional activity in transgenic Lotus corniculatus. A fusion construct between the lbI promoter and the GUS reporter gene was expressed mainly in the central zone of the root nodule, but the product was also detected in the non-nodule root zone and in roots in tissue culture. In roots of transgenic tobacco, the activity of the promoter was only 24% lower than in Lotus nodules. LulbI promoter activity was also detected in tobacco leaves. Lupine hemoglobin I has a higher sequence identity to symbiotic-type hemoglobins and thus it groups within the “Class II” hemoglobins. Received: 28 June 1999 / Accepted: 25 November 1999     

Hairy roots — a short cut to transgenic root nodules

To facilitate molecular studies of symbiotic nitrogen fixation a procedure for rapid production of transgenic root nodules was established on the legumeLotus corniculatus (Bird'sfoot trefoil). Regeneration of transgenic plants is not required as transgenic nodules are formed onAgrobacterium rhizogenes incited roots inoculated withRhizobium. Easy identification of transformed roots is possible using a set ofA. rhizogenes acceptor strains carrying assayable marker genes such as chloramphenicol acetyltransferase (CAT), -glucuronidase (GUS), or luciferase (LUC) under control of the cauliflower mosaic virus (CaMV) 35S promoter. Counterselection ofA. rhizogenes after infection of plants was improved using an auxotrophy marker.Abbreviations CAT chloramphenicol acetyltransferase - GUS -glucuronidase - LUC luciferase - Ri root inducing - TL left T-DNA - CaMV Cauliflower Mosaic Virus     

用于植物的铜诱导基因表达系统的改进

铜诱导基因表达系统已被用于植物转基因表达的时空调控.它由两部分构成:(1)组成型或器官专一性表达的acel基因编码铜反应性的转录因子;(2)融合启动子控制下的目的基因,融合启动子由含ACE1结合位点的金属反应元件(MRE)连接CaMV 35S(-90～+8)启动子组成.本实验测试了来自酵母金属硫蛋白基因5′调控区的两个不同的ACE1结合区域在转基因烟草(Nicotiana tabacum L. cv.W38)中的效果.结果表明,与MRE(-148～-105)相比,使用MRE(-210～-126)的铜诱导系统效率增加50%到100%.在植物生物技术中使用这一系统控制基因性状是很有潜力的.     

用于植物的铜诱导基因表达系统的改进

铜诱导基因表达系统已被用于植物转基因表达的时空调控。它由两部分构成：(1)组成型或器官专一性表达的aceI基因编码铜反应性的转录因子;(2)融合启动子控制下的目的基因,融合启动子由含ACE1结合位点的金属反应元件(MRE)连接CaMV 35S(-90- 8)启动子组成。本实验测试了来自酵母金属硫蛋白基因5′调控区的两个不同的AcE1结合区域在转基因烟草(Nicotiana tabacum L.cv.W38)中的效果。结果表明,与MRE(-148～-105)相比,使用MRE(-210～-126)的铜诱导系统效率增加50％到100％。在植物生物技术中使用这一系统控制基因性状是很有潜力的。     

Evaluation in tobacco of the organ specificity and strength of therolD promoter,domain A of the 35S promoter and the 35S2 promoter

In order to study the expression in plants of therolD promoter ofAgrobacterium rhizogenes, we have constructed chimaeric genes placing the coding region of thegusA (uidA) marker gene under control of tworolD promoter fragments of different length. Similar results were obtained with both genes. Expression studies were carried out in transformed R₁ progeny plants. In mature transformed tobacco plants, therolD-gus genes were expressed strongly in roots, and to much lower levels in stems and leaves. This pattern of expression was transmitted to progeny, though the ratio of the level of expression in roots relative to that in leaves was much lower in young seedlings. The degree of root specificity inrolD-gus transformants was less than that of a gene constructed with domain A of the CaMV 35S promoter,domA-gus, but the level of root expression was much higher than with the latter gene. However, the level of expression of therolD-gus genes was less than that of agus gene with a 35S promoter with doubled domain B, 35S²-gus. TherolD-gus genes had a distinctive pattern of expression in roots, compared to that of the two other genes, with the strongest GUS activity observed in the root elongation zone and in vascular tissue, and much less in the root apex.     

Transformation of tobacco and birdsfoot trefoil by lupin leghemoglobin I cDNA clone

The full length cDNA clone of leghemoglobin I gene fromLupinus luteus was placed under dual promoter into the plant expression vector pCB1399 and the resulting vector (pCB1415) was transfered into theAgrobacterium strain LBA4404 (pAL4404). The binary system LBA4404 (pAL4404, pCB1415) was then used for transformation ofNicotiana plumbaginifolia andLotus corniculatus. In both species kanamycin-resistant plants have been selected and regenerated. The synthesis of LbI protein in transformed plants has not been shown.     

Heritable transformation of tobacco byAgrobacterium-mediated transfer of theStreptomyces-derived herbicide resistance genebar

Thebar gene ofStreptomyces hygroscopicus encodes an enzyme that detoxifies the herbicide Basta. We have transferred theStreptotnyces-derived bar gene to tobacco through theAgrobacterium tumefaciens gene delivery system. Expression ofbar was driven by two different promoters, TR2’ or CaMV 35S, in two DNA constructs. TR2’ is a weak promoter in tobacco. CaMV 35S is, on the other hand, a strong promoter in tobacco, and transformation using the CaMV 35S promoter construct yielded Basta-resistant transgenic plants. Out of the over one hundred transformants obtained, most could be grown to maturity. Four of these were characterized by genetic and molecular methods. Subsequently, one of the four plants was not resistant and did not show presence ofbar DNA. The remaining three plants contained one or more copies ofbar DNA at one or two loci. Segregation data were consistent with this observation: we obtained ratios of either 3:1 (single locus) or 15:1 (two loci) Basta-resistant:Basta-sensitive in the F₂ generation. Field-grown plants showed resistance to Basta up to a level of 4000 g of active ingredient per hectare.     

Immunogold localization of nodule-enhanced phosphoenolpyruvate carboxylase in alfalfa

Phosphoenolpyruvate carboxylase (PEPC; EC 4-1-1-31) plays a paramount role in providing carbon for synthesis of malate and aspartate in alfalfa (Medicago sativa L.) root nodules. PEPC protein and activity levels are highly enhanced in N₂-fixing alfalfa nodules. To ascertain the relationship between the cellular location of PEPC and root nodule metabolism, enzyme localization was evaluated by immunogold cytochemistry using alfalfa nodule PEPC antibodies. Gold labelling patterns in effective nodules showed that PEPC is a cytosolic enzyme and is distributed relatively equally in infected and uninfected cells of the nodule symbiotic zone. A high amount of labelling was also observed in pericycle cells of the nodule vascular system. Labelling was also detected within inner cortical cells, but the density was reduced by 60%. When Lotus corniculatus was transformed with a chimeric gene consisting of the 5′-upstream region of the PEPC gene fused to β-glucuronidase (GUS), GUS staining in nodules was consistent with immunogold localization patterns. The occurrence of PEPC in both infected and uninfected cells of the symbiotic zone of effective nodules coupled to the reduced amounts in ineffective nodules suggests a direct role for this enzyme in supporting N₂-fixation. PEPC localization in the uninfected, interstitial cells of the symbiotic zone indicates that these cells may also have a role in nodule carbon metabolism. Moreover, the association of PEPC with the nodule vascular system implies a role for the enzyme in the transport of assimilates to and from the shoot.     

Effect of oxygen availability on nitrogen fixation by two Lotus species under flooded conditions

The pasture legumes Lotus uliginosus (Schk.) and Lotus corniculatus (L.), known to differ in their tolerance to flooding, were inoculated with Rhizobium loti and flooded for 60 d while subjected to two levels of dissolved pO2: 0.241 and 0.094 mol ml^-1. L. uliginosus showed significantly greater growth (shoot and root) and N2 fixation under both pO2s, compared to L. corniculatus, although growth and N2 fixation by L. corniculatus was not affected by the low pO2. Surprisingly, in L. uliginosus., growth, nodulation and N2 fixation were all increased by low pO2 while nodulation of L. corniculatus where low pO2 plants showed a significant increase over that of the higher pO2 plants while L. uliginosus plants showed a decline. Root porosity of L. uliginosus doubled in the low pO2-treatment from a mean of 14.5% in high pO2 roots to 28.5%, whereas that of L. corniculatus was relatively unaffected by pO2, being 7% and 9% for high and low pO2 plants, respectively. The structure of nodules differed little between species and treatments, although nodules/nodulated roots from the L. uliginosus plants had particularly profuse lenticels and aerenchyma. However, L. corniculatus nodules, especially those grown in the lower pO2 showed signs of early senescence with vacuolation of infected cells and green coloration when cut open. Leghaemoglobin (Lb) concentrations in nodules from both species were unaffected by low pO2, although that of L. corniculatus nodules, regardless of pO2, was significantly greater than L. uliginosus. Concentrations of the intercellular glycoprotein recognized by the monoclonal antibody MAC265 were significantly reduced in nodules from the low pO2 treatment in both species. Immunogold labelling showed that the MAC265 antigen was localized primarily within intercellular spaces within nodule cortices from both Lotus species. A marked decrease in deposition of the MAC265 antigen within the cortices of L. uliginosus nodules grown in the lower pO2, is discussed in terms of the relative abilities of the two Lotus spp. to maintain an O2 supply to the N2-fixing bacteroids within submerged nodules.Keywords: Lotus uliginosus, Lotus corniculatus, N2 fixation, flooding, oxygen.      

Differential expression of the Sesbania rostrata leghemoglobin glb3 gene promoter in transgenic legume and non-legume plants

The involvement of the Sesbania rostrata glb3 gene promoter NICE (nodule-infected cell expression) element in root-enhanced expression of 5-Srglb3-uidA-3nos chimeric gene was investigated in transgenic Nicotiana tabacum plants. The full-length wild-type Srglb3 promoter directed root meristem-enhanced expression in transgenic tobacco plants. The expression pattern of nine selected Srglb3 promoter mutations in the NICE element was examined in transgenic tobacco plants and compared with the pattern observed in nodules of transgenic Lotus corniculatus plants. The results suggest that the highly conserved motifs in the NICE element play an important role in expression in roots of non-legume plants.     

Regulation of nodulin gene expression

The expression of plant genes specifically induced during rhizobial infection and the early stages of nodule ontogeny (early nodulin genes) and those induced in the mature, nitrogen-fixing nodule (late nodulin genes) is differentially regulated and tissue/cell specific. We have been interested in the signal transduction pathway responsible for symbiotic, temporal and spatial control of expression of an early (Enod2) and a late (Leghemoglobin;lb) nodulin gene from the stem-nodulated legumeSesbania rostrata, and in identifying thecis-acting elements andtrans-acting factors involved in this process (De Bruijn and Schell, 1992). By introducing chimericS. rostrata lb promoter-gus reporter gene fusions into transgenicLotus corniculatus plants, we have been able to show that thelb promoter directs an infected-cell-specific expression pattern inLotus nodules. We have been able to delimit thecis-acting element responsible for nodule-infected-cell-expression to a 78 pb region of thelb promoter (NICE Element) and have analyzed this element in detail by site-specific mutagenesis. We have studied the interaction of the NICE element, and further upstreamcis-acting elements, withtrans-acting factors of both plant- and rhizobial origin. We have obtained evidence for the involvement of rhizobial proteins in infected-cell-specific plant gene expression (Welters et al., 1993). We have purified one of the bacterial binding proteins from theS. rostrata symbiontAzorhizobium caulinodans (AcBBP1), and cloned and mutated the corresponding gene, in order to examine its symbiotic phenotype. We have also found that theS. rostrata Enod2 gene is rapidly induced by physiologically significant concentrations of cytokinins, suggesting the role of cytokinin as a potential secondary signal involved in nodulation (Dehio and De Bruijn, 1992). We are examining whether the observed cytokinin induction, as well as the nodule-specific expression pattern, are modulated by theSrEnod2 promoter.     

The expression of a chimeric Phaseolus vulgaris nodulin 30-GUS gene is restricted to the rhizobially infected cells in transgenic Lotus corniculatus nodules

In Phaseolus vulgaris there is a nodulin family, Npv30, of ca. 30 kDa, as detected in an in vitro translation assay [2]. We isolated a gene (npv30-1) for one of the members of this family. The nucleotide sequence of the promoter of npv30-1 contains nodule-specific motifs common to other late nodulin genes. The promoter was fused to the GUS reporter gene; this chimeric fusion was introduced into Lotus corniculatus via Agrobacterium rhizogenes transformation. GUS activity was only detected in the infected cells of the nodules of transgenic plants. By contrast, the expression of a 35S-GUS construct was restricted to the uninfected cells and the vascular tissue.