Promoter regions of the extA extensin gene from Brassica napus control activation in response to wounding and tensile stress.

To identify controlling cis acting promoter regions in the B. napus extA extensin gene, expression in transgenic tobacco of 5 –159, –433, –664, –789 and –940 bp promoter truncations linked to the uidA (B-glucuronidase) reporter coding sequence were analysed. The –159 and –433 bp truncations directed non specific expression in all cell types within the plant. An activator region which increased expression levels 10 fold in all cell types was located between –159 to –433 bp. A repressor region was found between –664 to –789 bp; removal of this region resulted in a 15 fold increase in expression. Histochemical analysis showed that transgenics containing the –664, –789 and –940 bp truncations directed expression of the fusion gene only in the phloem. A negative regulatory region located between –433 to –664 bp repressed expression in non-phloem cell types. In areas of the plant subject to tensile stress, the repression exerted by the negative regulatory region was overcome, allowing expression in all cell types. The quantitative repressor and activator regions which controlled absolute expression levels in all cell types were seperate from the negative regulatory region which controlled cell type specific expression in response to tensile stress. A wound responsive region was found to be located between –940 to –3500 bp. Thus, the extA gene is under complex control, being regulated by 4 sets of positively and negatively acting cis regions, which control wound inducibility, activation in response to tensile stress, and quantitative expression levels.     

The Brassica napus extA extensin gene is expressed in regions of the plant subject to tensile stresses

The expression of extA, an extensin gene from Brassica napus L. (oilseed rape) was examined in transgenic Nicotiana tabacum L. (tobacco) and untransformed Brassica juncea L. and B. napus tissues. Northern analysis showed that this gene maintained its normal pattern of expression when transferred to tobacco. In transgenic tobacco plants containing an extA promoter/-glucuronidase coding sequence fusion, expression of extA was detected in the external and internal phloem of the main stem. High expression levels were seen in cortical parenchyma cells at the point where the axillary flowering branch joined the main stem. Expression was greatest in regions where the maximum tensile stress would seem to be exerted on the main stem by the weight of the axillary branch. It was confirmed that this expression pattern was due to tensile stress by using weights to induce expression of the fusion gene in axillary flowering stalks. In B. juncea pods, in-situ hybridisation studies showed that the extensin gene was strongly expressed in cells of the carpel walls within which considerable tensile stresses develop.Abbreviations GUS -glucuronidase - X-GLUC 5-bromo-4-chloro-3-indolyl glucuronide - SSC saline sodium citrate We thank the Biotechnology and Biological Sciences Research Council for funding this research, and Mrs. W. Grail for her expertise in histochemical technique. Ms. J. Spence is the recipient of a Biotechnology and Biological Sciences Research Council post-graduate studentship award.     

The Brassica napus extA extensin gene negative regulatory region controls expression in response to mechanical stresses

In the present study the hypothesis that the ?433 to ?664 bp negative regulatory region (NRR) of the Brassica napus extA extensin promoter controls extA activation in response to externally applied weight loads was tested. When weight loads were applied to the nodal regions of transgenic tobacco plants containing extA promoter deletions fused to GUS, repression controlled by the NRR was overcome and GUS expression was induced only in the transgenics carrying the NRR. This proves that extensin expression in nodal regions is not developmentally controlled, but is induced in response to mechanical stresses, and is controlled by the NRR. It was also shown that the activation of the extA promoter during the development of lateral roots is a stress‐related response that is also under the control of the NRR but that the constitutive expression of extensin mRNA in the phloem of roots is not due to the mechanical forces the root experiences as it forces it way through the soil. Electrophoretic mobility shift assays using a 25 bp oligonucleotide have been used to show that an 8 bp consensus sequence from the NRR binds nuclear proteins. Wound‐induced signals regulating extensin gene expression are shown to travel bi‐directionally through the plant, from root to leaf and vice versa.     

Tomato extensin and extensin-like cDNAs: structure and expression in response to wounding

Two tomato cDNA libraries were synthesized from poly(A)⁺ RNAs isolated from unwounded and wounded tomato stems. These cDNA libraries were packaged in gt10 and screened by in situ plaque hybridization with a tomato extensin gene clone (pTom 5.10). Several cDNA clones were identified and isolated from both libraries in this manner and subjected to restriction enzyme digestion, Southern gel blot hybridization, RNA gel blot hybridization, and DNA sequence analyses. From these analyses, the various cDNA clones were found to fall into one of five distinct classes (classes I–V). Class I clones hybridized to a 4.0 kb mRNA which accumulated markedly after wounding and encoded an extensin characterized largely by Ser-(Pro)₄-Ser-Pro-Ser-(Pro)₄-(Tyr)₃-Lys repeats. Class II clones hybridized to a 2.6 kb mRNA which showed no accumulation following wounding and encoded an extensin containing Ser-(Pro)₄-Ser-Pro-Ser-(Pro)₄-Thr-(Tyr)_1–3-Ser repeats. Class III clones hybridized to a 0.6 kb mRNA which greatly accumulated in response to wounding and encoded a glycine-rich protein (GRP) with (Gly)_2–6-Tyr-Pro and(Gly)_2–6-Arg repeats. Class IV clones contained both class I and class III DNA sequences and consequently hybridized to both the 4.0 kb and the 0.6 kb wound-accumulating mRNAs; these clones encoded a portion of a GRP sequence on one DNA strand and encoded a portion of an extensin sequence on the other DNA strand. Class V clones hybridized to a 2.3 kb mRNA which decreased following wounding and encoded a GRP sequence characterized by (Gly)_2–5-Arg repeats.     

Genome-wide association study dissects the genetic control of plant height and branch number in response to low-phosphorus stress in Brassica napus

Background and AimsOilseed rape (Brassica napus) is one of the most important oil crops worldwide. Phosphorus (P) deficiency severely decreases the plant height and branch number of B. napus. However, the genetic bases controlling plant height and branch number in B. napus under P deficiency remain largely unknown. This study aims to mine candidate genes for plant height and branch number by genome-wide association study (GWAS) and determine low-P-tolerance haplotypes.MethodsAn association panel of B. napus was grown in the field with a low P supply (P, 0 kg ha⁻¹) and a sufficient P supply (P, 40 kg ha⁻¹) across 2 years and plant height and branch number were investigated. More than five million single-nucleotide polymorphisms (SNPs) were used to conduct GWAS of plant height and branch number at two contrasting P supplies.Key ResultsA total of 2127 SNPs were strongly associated (P < 6·25 × 10⁻⁰⁷) with plant height and branch number at two P supplies. There was significant correlation between phenotypic variation and the number of favourable alleles of associated loci on chromosomes A10 (chrA10_821671) and C08 (chrC08_27999846), which will contribute to breeding improvement by aggregating these SNPs. BnaA10g09290D and BnaC08g26640D were identified to be associated with chrA10_821671 and chrC08_27999846, respectively. Candidate gene association analysis and haplotype analysis showed that the inbred lines carrying ATT at BnaA10g09290Hap1 and AAT at BnaC08g26640Hap1 had greater plant height than lines carrying other haplotype alleles at low P supply.ConclusionOur results demonstrate the power of GWAS in identifying genes of interest in B. napus and provided insights into the genetic basis of plant height and branch number at low P supply in B. napus. Candidate genes and favourable haplotypes may facilitate marker-based breeding efforts aimed at improving P use efficiency in B. napus.     

Spontaneous gene flow from rapeseed (Brassica napus) to wild Brassica oleracea

Research on the environmental risks of gene flow from genetically modified (GM) crops to wild relatives has traditionally emphasized recipients yielding most hybrids. For GM rapeseed (Brassica napus), interest has centred on the 'frequently hybridizing' Brassica rapa over relatives such as Brassica oleracea, where spontaneous hybrids are unreported in the wild. In two sites, where rapeseed and wild B. oleracea grow together, we used flow cytometry and crop-specific microsatellite markers to identify one triploid F1 hybrid, together with nine diploid and two near triploid introgressants. Given the newly discovered capacity for spontaneous introgression into B. oleracea, we then surveyed associated flora and fauna to evaluate the capacity of both recipients to harm cohabitant species with acknowledged conservational importance. Only B. oleracea occupies rich communities containing species afforded legislative protection; these include one rare micromoth species that feeds on B. oleracea and warrants further assessment. We conclude that increased attention should now focus on B. oleracea and similar species that yield few crop-hybrids, but possess scope to affect rare or endangered associates.     

Isolation and characterization of a homologous to lipase gene from Brassica napus

Lipase is an important lipolytic enzyme involved in plant lipid metabolism. To analyze its function and roles during seed germination and growth, a full-length cDNA encoding a homologous to lipase gene named BnLIP1 was cloned from Brassica napus, cv. Huyou 15, by rapid amplification of cDNA ends. The BnLIP1 gene had a total length of 1318 bp, with an open reading frame of 1170 bp encoding 389 amino acid residues. Sequence analysis revealed that BnLIP1 protein belonged to the GDSL family of serine esterases/lipases. In B. napus genome, BnLIP1 is represented by several copies with the length of 1601 bp, the gene comprises five exons and four introns. RT-PCR analysis indicated that BnLIP1 showed no tissue-specific expression during reproductive growth and is strongly expressed during seed germination. No expression could be detected until three days after germination, and its peak was registered at the fifth day after germination. In conclusion, BnLIP1-encoded protein is predicted to be a lipolytic enzyme widely expressed at various stages of oilseed rape germination and development. Published in Russian in Fiziologiya Rastenii, 2006, Vol. 53, No. 3, pp. 410–417. The text was submitted by the authors in English.     

Quantitative trait loci for root morphology in response to low phosphorus stress in Brassica napus

Phosphorus (P) deficiency in soils is a major limiting factor for crop growth worldwide. Changes in root morphology and architecture represent as an important mechanism of adaptation of plants to low P (LP) stress. To elucidate the genetic control of tolerance to P deficiency in Brassica napus, quantitative trait loci (QTL) for root morphology in response to LP were identified in three independent paper culture experiments, and dissected through QTL meta-analysis. In total, 62 significant QTL for total root length, root surface area, root volume, total dry weight, and plant P uptake under high and low P conditions were detected in the three experiments. Forty-five of these QTL were clustered within four linkage groups and were integrated into eight unique QTL by two rounds of QTL meta-analysis. Three of the unique QTL, uq.A1, uq.C3a and uq.C3b, were specific for LP condition. uq.C3a and uq.C3b were identified specifically for root traits and P uptake under LP stress, and may contribute to the adaptability of B. napus to P deficiency. Two functional markers, BnIPS2-C3 and BnGPT1-C3, which were developed from the genes AtIPS2 and AtGPT1 in Arabidopsis, were located in the confidence intervals of uq.C3a and uq.C3b, respectively. And AtGPT1 that corresponded to the interval of uq.C3b by in silico mapping was a possible candidate gene of uq.C3b. These results confirmed the importance of root traits for the adaptability of B. napus to LP and partially revealed the genetic basis of tolerance to P deficiency. These findings should be valuable for further study of the mechanism of P efficiency and the breeding of P-efficient cultivars by marker-assisted selection.     

Site-specific binding of a nuclear factor to the carrot extensin gene is influenced by both ethylene and wounding

Experiments conducted in vitro using the electrophoretic mobility shift assay have shown that a single region of the extensin gene of carrot (Daucus carota L.) interacts with a protein factor designated Extensin Gene Binding Factor-1 (EGBF-1) present in nuclear extracts obtained from carrot roots. This interaction is sequence-specific as judged by the failure of other plant gene sequences to compete with the extensin gene for EGBF-1 binding. The EGBF-1 activity is organspecific, not being expressed in nuclear extracts obtained from carrot leaves or stems. Both ethylene treatment and wounding of roots are shown to have a controlling influence on the expression of EGBF-1 activity in nuclear extracts. These results demonstrate that at least three distinct signals: ethylene treatment, wounding, and development, are important in determining the activity of EGBF-1 in nuclear extracts, and indicate a role for EGBF-1 in stress-related signal transduction and the regulation of extensin-gene expression.Abbreviations bp base pair(s) - EGBF extensin-gene binding factor - EMSA electrophoretic mobility shift assay - HRGP hydroxyproline-rich glycoprotein - kb kilobase     

Nitric oxide,calmodulin and calcium protein kinase interactions in the response of Brassica napus to salinity stress

• Involvement of nitric oxide (NO) in plant metabolism and its connection with phytohormones has not been fully described, thus information about the role of this molecule in signalling pathways remains fragmented. In this study, the effects of NO on calmodulin (CAM), calcium protein kinase (CPK), content of phytohormones and secondary metabolites in canola plants under salinity stress were investigated.
• We applied 100 μM sodium nitroprusside as an NO source to canola plants grown under saline (100 mM NaCl) and non-saline conditions at the vegetative stage.
• Plant growth was negatively affected by salinity, but exogenous NO treatment improved growth. NO caused a significant increase in activity of CAT, SOD and POX through their enhanced gene expression in stressed canola. Salinity-responsive genes, namely CAM and CPK, were induced by NO in plants grown under salinity. NO application enhanced phenolic compounds, such as gallic acid and coumaric acid and flavonoid compound,s catechin, diadzein and kaempferol, in plants subjected to salinity. NO treatment enhanced abscisic acid and brassinosteroids but decreased auxin and gibberellin in stressed canola plants.
• The impacts of NO in improving stress tolerance in canola required CAM and CPK. Also, NO signalling re-established the phytohormone balance and resulted in enhanced tolerance to salt stress. Furthermore, NO improved salinity tolerance in canola by increasing enzymatic and non-enzymatic antioxidant content.

     

Far upstream activating promoter regions are responsible for expression of the BnC1 cruciferin gene from Brassica napus

Summary Cruciferin is the major seed storage protein in Brassica napus. As much as 1.9 kbp of the BnC1 cruciferin gene promoter have been sequenced and analyzed. Promoter fragments with 5 deletions from –2500 to –v202 were fused with the ß-glucuronidase reporter gene and used for Nicotiana tabacum transformation. ß-glucuronidase could be specifically expressed in transgenic tobacco seeds under the control of the BnC1 promoter and regulatory elements were found to be dispersed over 1903 bp. An almost 5-fold increase in ß-glucuronidase expression was obtained when the promoter length was increased from –379 to –498, and another 10-fold increase was observed when sequences between –1266 and –1903 were added. Histochemical analysis shows that the region between –844 and –1266 directs the expression of the chimeric gene specifically to the root apical meristem.Abbreviations GUS ß-glucuronidase - MU 4-methyl umbelliferone - MUG 4-methyl-umbelliferyl-ß-D-glucuronide - X-gluc 5-bromo-4-chloro-3-indolyl-ß-D-glucuronide