Per L. Gregersen

Leaf senescence and nutrient remobilisation in barley and wheat

Extensive studies have been undertaken on senescence processes in barley and wheat and their importance for the nitrogen use efficiency of these crop plants. During the senescence processes, proteins are degraded and nutrients are re-mobilised from senescing leaves to other organs, especially the developing grain. Most of the proteins degraded reside in the chloroplasts, with Rubisco constituting the most dominant protein fraction. Despite intensive studies, the proteases responsible for Rubisco degradation have not yet been identified. Evidence for degradation of stromal proteins outside of chloroplasts is summarised. Rubisco is thought to be released from chloroplasts into vesicles containing stroma material (RCB = Rubisco-containing bodies). These vesicles may then take different routes for their degradation. Transcriptome analyses on barley and wheat senescence have identified genes involved in degradative, metabolic and regulatory processes that could be used in future strategies aimed at modifying the senescence process. The breeding of crops for characters related to senescence processes, e.g. higher yields and better nutrient use efficiency, is complex. Such breeding has to cope with the dilemma that delayed senescence, which could lead to higher yields, is correlated with a decrease in nutrient use efficiency. Pinpointing regulatory genes involved in senescence might lead to tools that could effectively overcome this dilemma.

Plant senescence and crop productivity

Senescence is a developmental process which in annual crop plants overlaps with the reproductive phase. Senescence might reduce crop yield when it is induced prematurely under adverse environmental conditions. This review covers the role of senescence for the productivity of crop plants. With the aim to enhance productivity, a number of functional stay-green cultivars have been selected by conventional breeding, in particular of sorghum and maize. In many cases, a positive correlation between leaf area duration and yield has been observed, although in a number of other cases, stay-green cultivars do not display significant effects with regards to productivity. In several crops, the stay-green phenotype is observed to be associated with a higher drought resistance and a better performance under low nitrogen conditions. Among the approaches used to achieve stay-green phenotypes in transgenic plants, the expression of the IPT gene under control of senescence-associated promoters has been the most successful. The promoters employed for senescence-regulated expression contain cis-elements for binding of WRKY transcription factors and factors controlled by abscisic acid. In most crops transformed with such constructs the stay-green character has led to increased biomass, but only in few cases to increased seed yield. A coincidence of drought stress resistance and stay-green trait is observed in many transgenic plants.

An epidermis/papilla-specific oxalate oxidase-like protein in the defence response of barley attacked by the powdery mildew fungus

A cDNA clone of a defence response transcript was isolated from a library prepared from barley leaves expressing papilla resistance towards the powdery mildew fungus, Blumeria (syn. Erysiphe) graminis f.sp. hordei (Bgh). The 904 bp sequence encodes a 229 amino acid polypeptide with a putative signal peptide of 23 amino acids. After cleavage, the protein has a mass of 22.3 kDa and exhibits up to 60% amino acid identity to certain dicot proteins, and 46% amino acid identity to barley oxalate oxidase; therefore we designated it HvOxOLP (for Hordeum vulgare oxalate oxidase-like protein). Single-base substitutions among several cDNA and RACE clones demonstrate a gene of many copies. Both the transcript and protein accumulate from 3 h after inoculation with Bgh. The transcript level peaks at 18–24 h and subsequently decreases, whereas the protein level is stable from 24 h after inoculation. The accumulation patterns are independent of the outcome of the barley/powdery mildew interaction, unlike that of PR proteins, for example. The transcript accumulates specifically in the inoculated epidermal tissue. This temporal and spatial expression pattern suggests a very close relationship to papilla formation. Immunoblot analyses have facilitated a demonstration that HvOxOLP, like oxalate oxidase, is a water-soluble 100 kDa oligomeric protein. The oligomer is heat-stable and SDS-tolerant, and it can be denatured into a 25 kDa monomer. Attempts to demonstrate oxalate oxidase activity for this protein have failed. However, the relationships to oxalate oxidase suggests that HvOxOLP may be involved in H2O2 generation necessary for, for example, cross-linking of cell wall components during formation of papillae.

The HvNAC6 transcription factor: a positive regulator of penetration resistance in barley and Arabidopsis

Pathogens induce the expression of many genes encoding plant transcription factors, though specific knowledge of the biological function of individual transcription factors remains scarce. NAC transcription factors are encoded in plants by a gene family with proposed functions in both abiotic and biotic stress adaptation, as well as in developmental processes. In this paper, we provide convincing evidence that a barley NAC transcription factor has a direct role in regulating basal defence. The gene transcript was isolated by differential display from barley leaves infected with the biotrophic powdery mildew fungus, Blumeria graminis f.sp. hordei (Bgh). The full-length cDNA clone was obtained using 5′-RACE and termed HvNAC6, due to its high similarity to the rice homologue, OsNAC6. Gene silencing of HvNAC6 during Bgh inoculation compromises penetration resistance in barley epidermal cells towards virulent Bgh. Complementing the effect of HvNAC6 gene silencing, transient overexpression of HvNAC6 increases the occurrence of penetration resistant cells towards Bgh attack. Quantitative RT-PCR shows the early and transient induction of HvNAC6 in barley epidermis upon Bgh infection. Additionally, our results show that the Arabidopsis HvNAC6 homologue ATAF1 is also induced by Bgh and the ataf1-1 mutant line shows decreased penetration resistance to this non-host pathogen. Collectively, these data suggest a conserved role of HvNAC6 and ATAF1 in the regulation of penetration resistance in monocots and dicots, respectively.

cDNA cloning and characterization of two barley peroxidase transcripts induced differentially by the powdery mildew fungus Erysiphe graminis

Abstract A cDNA library of RNA from barley leaves inoculated with Erysiphe graminis was screened using labelled cDNA enriched for specific sequences by subtractive hybridization against RNA from non-inoculated leaves. This resulted in isolation of several clones representing pathogen induced genes. By cross-hybridization and sequence analysis, one of the cDNAs (pBT6-3) was found to be a partial clone representing a putative peroxidase, for which a full-length cDNA clone (pBH6-301) was subsequently isolated. The predicted amino acid sequence revealed a 21 amino acid signal peptide and a 294 amino acid mature protein (31 kDa) and shows 56 % amino acid identity to a basic peroxidase from turnip, 89 % to a putative peroxidase from wheat, but only 38% to the amino acid sequence derived from the cDNA clone (pcD1311) of a second putative barley peroxidase expressed in leaves. Northern blot analysis showed that the pBT6-3 (pBH6-301) transcript is elevated as early as 4 h after inoculation with E. graminis f. sp. hordei and that two maxima in transcript levels appear, which can be correlated with penetration attempts by the fungus. The amount of the pcD1311 transcript was also found to increase in inoculated leaves but at a later time point.

Association of hydrogen peroxide with restriction of Septoria tritici in resistant wheat

Abstract Infection of wheat by Septoria tritici was studied in a compatible (cultivar ‘Sevin’-isolate IPO323) and an incompatible (cultivar ‘Stakado’-isolate IPO323) interaction. A second incompatible interaction (cultivar ‘Flame’-isolate IPO323) was included as a control of the most important observations made for Stakado. Quantitative studies of the initial stages of infection confirmed that penetration occurs through stomata. However, direct penetration attempts were also observed, indicated by papilla-formation. Pre-penetration growth and penetration frequency was not different between the interactions. Hyphal growth in Stakado was inhibited after penetration and no pycnidia formed whereas in Sevin, hyphal growth progressed and pycnidia formed 15 days after inoculation. Significantly higher amounts of H2O2 accumulated in Stakado than in Sevin until 11 days after inoculation. Timing and localization of H2O2 in Stakado correlated with arrest of pathogen growth, thus indicating a role for this molecule in resistance. H2O2 accumulation is known to arrest biotrophic pathogens and therefore also likely the hemibiotrophic pathogen S. tritici. More H2O2 accumulated in Sevin than Stakado 13 and 15 days after inoculation, coinciding with pycnidium formation and host cell collapse. This late accumulation in the compatible interaction is thought to be a stress-related response. After inoculation with S. tritici, total peroxidase activity and gene transcript of an apoplastic peroxidase increased in Stakado. The peroxidase activity pattern and transcript accumulation profile suggest a role for peroxidase in resistance, probably in cell wall cross-linking. Accumulation patterns of the gene transcript of a catalase and the total catalase enzyme activity suggest roles for catalase synthesis and inactivation in regulating H2O2 accumulation.

A roadmap for zinc trafficking in the developing barley grain based on laser capture microdissection and gene expression profiling

Nutrients destined for the developing cereal grain encounter several restricting barriers on their path towards their final storage sites in the grain. In order to identify transporters and chelating agents that may be involved in transport and deposition of zinc in the barley grain, expression profiles have been generated of four different tissue types: the transfer cells, the aleurone layer, the endosperm, and the embryo. Cells from these tissues were isolated with the ‘laser capture microdissection’ technology and the extracted RNA was subjected to three rounds of T7-based amplification. The amplified RNA was subsequently hybridized to Affymetrix 22K Barley GeneChips. Due to the short average length of the amplified transcripts and the positioning of numerous probe sets at locations more than 400 base pairs (bp) from the poly(A)-tail, a normalization approach was used where the probe positions were taken into account. On the basis of the expression levels of a number of metal homeostasis genes, a working model is proposed for the translocation of zinc from the phloem to the storage sites in the developing grain.

A chalcone synthase with an unusual substrate preference is expressed in barley leaves in response to UV light and pathogen attack

A cDNA clone was isolated by differential hybridization from a library prepared from barley leaves inoculated with the fungus Blumeria graminis f.sp. hordei (Bgh). The open reading frame of the insert (designated HvCHS2) encoded a polypeptide with 72–79% identity to chalcone synthases (CHS) and 65–68% identity to stilbene synthases. Alignments of the amino acid sequence of HvCHS2 with the consensus sequence of naringenin-CHS (EC 2.3.1.74) reveals significant differences between HvCHS2 and naringenin-CHS. HvCHS2 transcripts accumulate strongly in barley leaves in response to inoculation with Bgh, whereas only insignificant accumulation of barley naringenin-CHS (CHS1) transcripts is seen upon the inoculation. The accumulation of HvCHS2 transcripts is also elicited by UV light. To compare the activity of HvCHS2 with the activity of CHS1, the two enzymes were expressed in Escherichia coli. Both HvCHS2 and CHS1 catalyse the formation of chalcones. However, HvCHS2 and CHS1 differ in their substrate requirements. CHS1 uses cinnamoyl-CoA and 4-coumaroyl-CoA at comparable rates whereas feruloyl-CoA is a poor substrate for this enzyme. In contrast, HvCHS2 converts feruloyl-CoA and caffeoyl-CoA at the highest rate whereas cinnamoyl-CoA is a poor substrate. Thus, HvCHS2 is a novel pathogen and UV light induces homoeriodictyol/eriodictyol CHS involved in the direct production of flavonoids possessing multi-substituted B-rings.

A microarray-based comparative analysis of gene expression profiles during grain development in transgenic and wild type wheat.

Global, comparative gene expression analysis is potentially a very powerful tool in the safety assessment of transgenic plants since it allows for the detection of differences in gene expression patterns between a transgenic line and the mother variety. In the present study, we compared the gene expression profile in developing seeds of wild type wheat and wheat transformed for endosperm-specific expression of an Aspergillus fumigatus phytase. High-level expression of the phytase gene was ensured by codon modification towards the prevalent codon usage of wheat genes and by using the wheat 1DX5HMW glutenin promoter for driving transgene expression. A 9K wheat unigene cDNA microarray was produced from cDNA libraries prepared mainly from developing wheat seed. The arrays were hybridised to flourescently labelled cDNA prepared from developing seeds of the transgenic wheat line and the mother variety, Bobwhite, at three developmental stages. Comparisons and statistical analyses of the gene expression profiles of the transgenic line vs. that of the mother line revealed only slight differences at the three developmental stages. In the few cases where differential expression was indicated by the statistical analysis it was primarily genes that were strongly expressed over a shorter interval of seed development such as genes encoding storage proteins. Accordingly, we interpret these differences in gene expression levels to result from minor asynchrony in seed development between the transgenic line and the mother line. In support of this, real time PCR validation of results from selected genes at the late developmental stage could not confirm differential expression of these genes. We conclude that the expression of the codon-modified A.␣fumigatus phytase gene in the wheat seed had no significant effects on the overall gene expression patterns in the developing seed.

A flavonoid 7-O-methyltransferase is expressed in barley leaves in response to pathogen attack

We have shown previously that transcripts corresponding to the cDNA clone pBH72-F1, with similarities to O-methyltransferases (OMT), accumulated in barley leaves in response to attack by the pathogenic fungus Blumeria graminis (Plant Mol Biol 26 (1994) 1797). To investigate the accumulation pattern in the defence response and the organ localization of the pBH72-F1-encoded polypeptide (F1-OMT), an antiserum was raised against Escherichia coli expressed F1-OMT. The 43 kDa protein was absent in normal leaves but accumulated strongly in response to pathogen attack. The F1-OMT protein accumulated faster in barley lines inoculated with an avirulent B. graminis isolates compared to a virulent isolate. Additionally, F1-OMT related proteins were detected in developing kernels. F1-OMT was expressed as a functional enzyme in E. coli and the substrate specificity was investigated. The enzyme exhibited OMT activity towards flavonoid aglycones with the highest activity against apigenin (4′,5,7-trihydroxyflavone). In contrast, caffeic acid did not serve as substrate for F1-OMT. The product of F1-OMT was analyzed by HPLC and GC-MS and found to be genkwanin (4′,5-dihydroxy-7-methoxyflavone). Initial velocity data were best represented by a sequential bi-bi mechanism, and kinetic parameters of KSAM=10.9µM,Kapigenin=4.6µM and a specific activity of 0.45 µkat/g were obtained. Barley F1-OMT, apigenin 7-O-methyltransferase, is suggested to be involved in the production of a methylated flavonoid phytoalexin.