Leaf senescence is the final developmental stage of a leaf. The progression of barley primary leaf senescence was followed by measuring the senescence‐specific decrease in chlorophyll content and photosystem II efficiency. In order to isolate novel factors involved in leaf senescence, a differential display approach with mRNA populations from young and senescing primary barley leaves was applied. In this approach, 90 senescence up‐regulated cDNAs were identified. Nine of these clones were, after sequence analyses, further characterized. The senescence‐associated expression was confirmed by Northern analyses or quantitative RealTime‐PCR. In addition, involvement of the phytohormones ethylene and abscisic acid in regulation of these nine novel senescence‐induced cDNA fragments was investigated. Two cDNA clones showed homologies to genes with a putative regulatory function. Two clones possessed high homologies to barley retroelements, and five clones may be involved in degradation or transport processes. One of these genes was further analysed. It encodes an ADP ribosylation factor 1‐like protein (HvARF1) and includes sequence motifs representing a myristoylation site and four typical and well conserved ARF‐like protein domains. The localization of the protein was investigated by confocal laser scanning microscopy of onion epidermal cells after particle bombardment with chimeric HvARF1‐GFP constructs. Possible physiological roles of these nine novel SAGs during barley leaf senescence are discussed.

Phytohormones are not only instrumental in regulating developmental processes in plants but also play important roles for the plant's responses to biotic and abiotic stresses. In particular, abscisic acid, ethylene, jasmonic acid, and salicylic acid have been shown to possess crucial functions in mediating or orchestrating stress responses in plants. Here, we review the role of salicylic acid and jasmonic acid in pathogen defence responses with special emphasis on their function in the solanaceous plant potato.

Among the plant hormones jasmonic acid and related derivatives are known to mediate stress responses and several developmental processes. Biosynthesis, regulation, and metabolism of jasmonic acid in Arabidopsis thaliana are reviewed, including properties of mutants of jasmonate biosynthesis. The individual signalling properties of several jasmonates are described.

Transport processes between plant and fungal cells are key elements in arbuscular mycorrhiza (AM), where H+‐ATPases are considered to be involved in active uptake of nutrients from the symbiotic interface. Genes encoding H+‐ATPases were identified in the genome of Medicago truncatula and three cDNA fragments of the H+‐ATPase gene family (Mtha 1 ‐ 3) were obtained by RT‐PCR using RNA from M. truncatula mycorrhizal roots as template. While Mtha 2 and Mtha 3 appeared to be constitutively expressed in roots and unaffected by AM development, transcripts of Mtha 1 could only be detected in AM tissues and not in controls. Further analyses by RT‐PCR revealed that Mtha 1 transcripts are not detectable in shoots and phosphate availability did not affect RNA accumulation of the gene. Localization of transcripts by in situ hybridization on AM tissues showed that Mtha 1 RNA accumulates only in cells containing fungal arbuscules. This is the first report of arbuscule‐specific induced expression of a plant H+‐ATPase gene in mycorrhizal tissues.

Conventional and analytical electron microscopy (EDX, ESI, EELS) were used to investigate the silicon accumulation, the chemical nature of the Si deposits and their formation in three species of monocotyledons. In Deschampsia , in particular parts of the outer epidermal cell wall silicon is accumulated as silicic acid. Electron dense, needle‐shaped crystals in the vacuoles of epidermal cells and in the intercellular spaces were also identified as silicic acid. In xylem parenchyma cells, silicon is accumulated as SiO2, which is formed from Sn silicate. In Festuca , crystal‐like deposits of SiO2 occur on the epidermal surface, in the epidermal and parenchyma cell walls, and in vacuoles of bundle sheath cells. Often the deposits disturb the cell walls and penetrate the envelope of plastids and mitochondria. The crystal‐like SiO2 deposits originate from Sn silicate. In the pericarp of ripe nuts of Schoenus , no stainable cell wall components are detected. The inner part of the pericarp consists of silicic acid, while in the outer regions small clusters of silicic acid are embedded in a matrix of SiO2. The silicic acid deposits show an unusual, layered structure, typical for lepidoic silicic acids, which consist of two‐dimensional crystals lying one above the other.

Treatment of barley leaf segments with jasmonic acid methyl ester (JM) leads to the accumulation of a set of newly formed abundant proteins. Among them, the most abun dant protein exhibits a molecular mass of 23 kDa (JIP‐23). Here, data are presented on the occurrence and expression of the lIP‐23 genes in different cultivars of Hordeum vulgare . Southern blot analysis of 80 cultivars revealed the occurrence of 2 to 4 genes coding for JIP‐23 in all cultivars. By means of Northern blot and immunoblot analysis it is shown that some cultivars lack the ex pression of jip‐23 upon treatment of primary leaves with JM as well as upon stress performed by incubation with 1 M sorbitol solution. During germination, however, all tested cultivars ex hibited developmental expression of jip‐23 . The results are dis cussed in terms of possible functions of JIP‐23 in barley.