Effect of Low Temperature lmbibition on Mito chondrium Respiration and Phosphorylation of PEG Primed Soybean Seed

Cotyledon mitochondrium respiration and oxidative phosphorylation activity of PEG primed and unprimed (control) soybean seeds which have been exposed to low temperature imbibition before germination are studied. The ADP stimulated respiration rates of control mitochondria are evidently higher than state Ⅲ respiration rates of mitochondria from primed seed when L-Mal, α-Kg and Succ are used as substrates respectively. The mitochondria from the unprimed do not possess respiratory control (RC.) On the contrary, mitochondria from the primed, even after seeds being exposed to 2–3 ℃ imbibition for 24 h, phosphorylate normally. The ADP/O and RC values are consistent with those of theoretical expectation. When NADH is used as substrate, unprimed seed mitochondria still possess oxidative phosphorylation activity, while ADP/O and RC values are obviously lower than those of mitochondria from the primed. The emerging sequence of the activity of the diverse phosphorylation sites during germination is also studied. When a different substrate is used, the emerging sequence of the primed is as follows: 1. NADH (12 h), 2.α-Kg (24 h), 3. L-Mal and Succ (48 h). This corresponds to occurrence sequence of ADP stimulated respiration in control mitochondria. The above results show that low temperature imbibition has an irreversible destructive effect on oxidative phosphorylation activity of control mitochondria, and PEG priming has a protective effect on structure and function of the mitochondria under low temperature imbibition stress. The mechanism of soybean imbibitional chilling injury and protective effect of PEG priming are discussed.     

A new approach to the molecular analysis of docking, priming, and regulated membrane fusion

Studies using isolated sea urchin cortical vesicles have proven invaluable in dissecting mechanisms of Ca²⁺-triggered membrane fusion. However, only acute molecular manipulations are possible in vitro. Here, using selective pharmacological manipulations of sea urchin eggs ex vivo, we test the hypothesis that specific lipidic components of the membrane matrix selectively affect defined late stages of exocytosis, particularly the Ca²⁺-triggered steps of fast membrane fusion. Egg treatments with cholesterol-lowering drugs resulted in the inhibition of vesicle fusion. Exogenous cholesterol recovered fusion extent and efficiency in cholesterol-depleted membranes; α-tocopherol, a structurally dissimilar curvature analogue, selectively restored fusion extent. Inhibition of phospholipase C reduced vesicle phosphatidylethanolamine and suppressed both the extent and kinetics of fusion. Although phosphatidylinositol-3-kinase inhibition altered levels of polyphosphoinositide species and reduced all fusion parameters, sequestering polyphosphoinositides selectively inhibited fusion kinetics. Thus, cholesterol and phosphatidylethanolamine play direct roles in the fusion pathway, contributing negative curvature. Cholesterol also organizes the physiological fusion site, defining fusion efficiency. A selective influence of phosphatidylethanolamine on fusion kinetics sheds light on the local microdomain structure at the site of docking/fusion. Polyphosphoinositides have modulatory upstream roles in priming: alterations in specific polyphosphoinositides likely represent the terminal priming steps defining fully docked, release-ready vesicles. Thus, this pharmacological approach has the potential to be a robust high-throughput platform to identify molecular components of the physiological fusion machine critical to docking, priming, and triggered fusion.     

Crop residue-derived dissolved organic matter accelerates the decomposition of native soil organic carbon in a temperate agricultural ecosystem

Crop residue-derived dissolved organic matter (DOM) plays an important role in soil carbon (C) cycling. To investigate the effects of maize residue-derived DOM and urea additions on the native soil organic carbon (SOC) decomposition and soil net C balance a pot experiment was carried out during the winter wheat growing season in the North China Plain (NCP). The results showed that adding maize residue-derived DOM alone (RDOM) or together with urea (RDOM?+?N) accelerated the decomposition of native SOC and resulted in a net SOC loss. The net loss of SOC was 3.90?±?0.61 and 3.53?±?0.48?g?C?m^?2 in RDOM and RDOM?+?N treatments, respectively. The stimulatory effect of per unit DOM-C addition on the native SOC decomposition was 0.25?±?0.05 and 0.45?±?0.07 for the RDOM and RDOM?+?N treatments, respectively. Increases in the microbial biomass and the activity of β-glucosidase, invertase and cellobiohydrolase as well as soil mineral N content were responsible for a more intense priming effect in DOM-amended soils. The positive relationship between primed soil C and soil available N (R?=?0.76, P?<?0.05) suggested that the stimulation of decomposition of native SOC by DOM addition would be enhanced by nitrogen fertilizer application.     

Performance of carrot and onion seed primed with beneficial microorganisms in glasshouse and field trials

Beneficial microorganisms (Clonostachys rosea IK726, Pseudomonas chlororaphis MA342, Pseudomonas fluorescens CHA0, Trichoderma harzianum T22 and Trichoderma viride S17a) were successfully applied to carrot and onion seed during a commercial drum priming process. Applied microorganisms were recovered above the target of at least 1 × 10⁵ cfu g⁻¹ seed following subsequent application of pesticides to the seed according to standard commercial practices of film-coating carrot and pelletting onion seed. Two glasshouse experiments consistently showed that priming improved emergence of carrot seed and that C. rosea IK726 further improved emergence time. Priming improved emergence of onion seed in one glasshouse experiment, but had an unexpected negative effect on emergence in the second experiment, possibly due to the proliferation of an unidentified indigenous microorganism during priming, becoming deleterious in high numbers. In this experiment, the application of beneficial microorganisms during priming negated this effect and significantly improved emergence. For each crop, a series of field trials was also carried out over three years, at two different sites each year. Although some positive effects of different seed treatments were seen on emergence or yield in individual field trials, no consistent effects were found for primed or microorganism-treated seed across all sites and years. However, a combined analysis of data for all years and sites indicated that pesticide application did consistently improve emergence and yield for both carrot and onion. This is the first comprehensive study assessing glasshouse and field performance of carrot and onion seed primed with beneficial microorganisms during a commercial process of drum priming in the UK.     

Priming,signaling, and protein production associated with induced resistance by <Emphasis Type="Italic">Bacillus amyloliquefaciens</Emphasis> KPS46

Bacillus amyloliquefaciens KPS46 is a rhizobacterium that induces systemic protection in soybean (Glycine max L.) against several diseases and enhances plant growth. In this study, treatment of soybean seed with KPS46 provided protection to leaves from bacterial pustule, caused by Xanthomonas axonopodis pv. glycines (Xag). KPS46 treatment also increased phenolic content and β-1,3-glucanase and peroxidase activity levels in leaves over non-treated plants. Differential expression of these traits was more rapid and pronounced when KPS46 treated plants were infected with Xag, this pattern indicating priming. Also associated with induced resistance by KPS46 was increased production of salicylic acid (SA) and jasmonic acid (JA) in soybean leaves, suggesting both SA- and JA-dependent signaling pathways are systemically triggered by KPS46 seed treatment. When KPS46 was applied to Arabidopsis roots, however, resistance against Pseudomonas syringae pv. tomato (Pst) was induced only in host genotypes with intact jasmonate, ethylene, and auxin sensitivity. Thus, induced resistance against Pst by KPS46 was SA independent and JA/ethylene dependent. Proteins induced in soybean leaves by KPS46 seed treatment and by the seed treatment in combination with pathogen inoculation were determined by proteomic analysis. Among 20 proteins upregulated in KPS46-treated plants, compared with non-treated plants, only three were defense related. In plants that received both KPS46 treatment and inoculation with Xag, nine of the 20 upregulated protein, as compared with proteins produced Xag inoculated plants having no KPS46 treatment, were defense related. This pattern of increased induction of defense-related proteins following pathogen infection of KPS46 treated plants supported priming by KPS46. Aside from proteins with defense-related function, most of the proteins induced by KPS46 were involved in metabolism and energy conversion, reflecting the strong direct positive effect that KPS46 has on soybean growth.     

Spent growth medium of Pantoea agglomerans primes wheat suspension cells for augmented accumulation of hydrogen peroxide and enhanced peroxidase activity upon elicitation

Induced disease resistance in plants is based on multiple mechanisms, including cell “priming”, i.e. an enhancement of the capacity to mobilize cellular defense responses upon pathogen attack. Potent inducers of priming are, for example, salicylic acid, synthetic compounds such as a benzothiadiazole, and certain rhizosphere bacteria. While priming is well characterized for a number of dicot plants, only few cases of priming are documented in monocots. Here, we report that the spent growth medium of the Gram negative bacterium Pantoea agglomerans is capable of priming wheat cells (Triticum aestivum L. cv Prelude-Sr5) for elicitor-induced defense responses. Pre-incubation of suspension-cultured wheat cells with growth medium of P. agglomerans led to a strong enhancement of an oxidative burst that has been induced by chitin or chitosan and to an increase in extracellular peroxidase activity. Moreover, exopolysaccharides (EPS) were isolated from the spent growth medium and demonstrated to be sufficient for the induction of H₂O₂ priming. The EPS-induced priming was shown to be time- and concentration-dependent. We conclude that EPS are the or one of several priming-active component(s) in the spent growth medium of P. agglomerans. The present work is the first report of priming in a monocot plant by a specific component of bacterial origin. A comparison with known chemical inducers of resistance revealed that a benzothiadiazole was able to enhance the oxidative burst similar to the spent growth medium or the EPS of P. agglomerans, while salicylic acid was not.     

The effects of osmotic pre-sowing treatment on laboratory germination in a range of wild flower species

Sown seed of many wild flower species have slow or delayed germination which can allow unsown and undesirable species to colonise a prepared site. Ideally all seed sown should germinate immediately. Priming seed in an inert osmoticum can improve synchronisation and speed of germination. The objective of this study was to assess the efficacy of priming on a selection of 60 wild flower species from a total of 21 different families. The majority of the species selected were common constituents of commercial seed mixtures. Seeds were primed in the light at 15^CC for 14 days in a polyethylene glycol ‘6000’ solution giving an osmotic potential of either -10 or -15 bars. Priming had a highly significant effect on speed of germination reducing the median germination time by 2.8 ± 0.27 days in the -10 bar treatment and 1.6 ± 0.27 days in the -15 bar treatment. At the species level, 28 species had significantly reduced median germination times following priming. Priming significantly enhanced the final germination percentage in 15 species and significantly reduced it in eight species, with the adverse effect being more pronounced at -15 bars than at -10 bars. Non-hierarchical cluster analysis showed no clear patterns in response to priming either in relation to the comparative ecology or the plant family of the species tested, with the possible exception of the Leguminosae species. Only one out of six members of this family showed any enhancement in germination rate or percentage. The study demonstrates that a priming treatment could improve speed of germination, in a wide range of commonly sown semi-natural grassland species.     

神经元突触囊泡循环的分子机理

神经末梢突触囊泡循环包括锚靠、出胞、入胞及囊泡再生等步骤,由囊泡、轴浆及突触前膜的多种蛋白质的级联反应介导,其关键步骤的分子模型的确立,为进一步了解神经系统高级活动奠定了基础。     

Differential inducible defense mechanisms against bacterial speck pathogen in Arabidopsis thaliana by plant-growth-promoting-fungus Penicillium sp. GP16-2 and its cell free filtrate

Although a wealth of information is available regarding resistance induced by plant growth-promoting rhizobacteria (PGPR), not much is known about plant growth-promoting fungi (PGPF). Hence, the goal of the present research was to provide more information on this matter. In Arabidopsis thaliana L., root colonizing PGPF Penicillium sp. GP16-2 or its cell free filtrate (CF) elicited an induced systemic resistance (ISR) against infection by Pseudomonas syringae pv. tomato DC3000 (Pst), leading to a restriction of pathogen growth and disease development. We demonstrate that signal transduction leading to GP16-2-mediated ISR requires responsiveness to JA and ET in a NPR1-dependent manner, while CF-mediated ISR shows dispensability of SA, JA, ET and NPR1-dependent signaling (at least individually). In addition, root colonization by GP16-2 is not associated with a direct effect on expression of known defense-related genes, but potentiates the activation of JA/ET-inducible ChitB, which only becomes apparent after infection by Pst. However, CF-mediated ISR was partly associated with the direct activation of marker genes responsive to both SA and JA/ET signaling pathways and partly associated with priming, leading to activation of JA-/ET-inducible ChitB and Hel genes. These suggest that CF may contain one or more elicitors that induce resistance by way where at least SA, JA and ET may play a role in defense signaling in Arabidopsis. Therefore, defense gene changes and underlying signaling pathways induced by Penicillium sp. GP16-2 root colonization and its CF application are not the same and only partially overlap.     

Lagging strand replication of rolling-circle plasmids in <Emphasis Type="Italic">Streptomyces lividans</Emphasis>: an RNA polymerase-independent primer synthesis

The rolling circle (RC) mechanism of DNA replication generating single-stranded DNA (ssDNA) intermediates is common in various high-copy circular plasmids in Streptomyces, and the ssDNA released after leading strand synthesis is converted to its double-stranded form (dsDNA) by the host proteins. The in vivo and in vitro lagging strand syntheses from ssDNA replicative intermediates of RC plasmid pSN22 in Streptomyces lividans was characterized. The presence or absence of the single-strand origin (sso), the replication initiation site of lagging strand synthesis, did not significantly affect the copy numbers of pSN22 derivatives. In vivo lagging strand synthesis was not affected by the rifampicin inhibition of S. lividans RNA polymerase. Likewise, in vitro lagging strand synthesis using cell-free extracts revealedsso-independent, rifampicin-resistant lagging strand synthesis in S. lividans. Although all four dNTPs are usually required for the initiation of such synthesis, the presence of only one NTP was sufficient to carry outlagging strand synthesis in vitro. Interestingly, the cell-free extract of exponential-phase cells required less ATP than that of stationary-phase cells. These results reveal a predominant RNA polymerase-independent priming system in S. lividans that may be a result of the stabilization of RC plasmids lacking sso in S. lividans.