Update on the possible mode of action of the jasmonates: Focus on the metabolism of cell wall polysaccharides in relation to growth and development

Jasmonic acid (JA) and its related compounds (jasmonates) applied to plant tissues exert either inhibitory or promotive effects in growth and developmental processes, which in some ways are similar to abscisic acid. However, little is known about the mode of action of the jamonates at the tissue or organ levels. Here, we review partial evidence for the physiological action of the jasmonates on cell elongation and abscission.
Jasmonates inhibit the IAA-induced cell elongation of oat coleoptile segments not by affecting energy production, osmoregulation and cell wall loosening, but by inhibiting the synthesis of cell wall polysaccharides. The inhibition is partially reversed by simultaneous application of sucrose. Inhibition of IAA-induced elongation by JA is only observed in monocotyledons, not in dicotyledons. These effects suggest that jasmonates exert their inhibitory effect on cell elongation by affecting the metabolism of the cell wall polysaccharides in monocotyledons.
Jasmonates promote the abscission of bean petiole explants without enhancing ethylene production. Cells in the petiole adjacent to the abscission zone expand during abscission. In the abscission zone, jasmonates decrease the amount of cellulosic but not that of noncellulosic polysaccharides. Jasmonates increase the activities of cellulase and decrease the levels of UDP-sugars, which are important intermediates for the synthesis of cell wall polysaccharides in the abscission zone, probably resulting in the decreased level of cellulose and the mechanical weakness of cell walls.
Thus, it is suggested that jasmonates exert their multiple physiological effects by affecting the metabolic processes of cell wall polysaccharides.     

Engage the hodgepodge: management factors are essential when prioritizing areas for restoration and conservation action

Restoration and conservation initiatives, such as the eradication of invasive alien plants, should be guided by scientific evidence. Typically, ecological data alone is used to inform the decision‐making of these initiatives. Recent advances in the mapping of conservation opportunity include a diverse range of scientifically‐identified factors that determine the feasibility and likely effectiveness of conservation initiatives, and include, for example, data on the willingness and capacity of land managers to be effectively involved. Social research techniques such as interview surveys, phenomenology, and social network analysis are important approaches for securing useful human and social data. These approaches are yet to be widely adopted in restoration initiatives, but could be usefully applied to improve the effective implementation of these initiatives. Restoration and conservation planners will deliver spatial prioritisations which provide more effective and cost‐efficient decision‐making if they include not simply ecological data, but also data on economic, human, management, social and vulnerability factors that determine implementation effectiveness.     

MauE and MauD proteins are essential in methylamine metabolism of Paracoccus denitrificans

Synthesis of enzymes involved in methylamine oxidation via methylamine dehydrogenase (MADH) is encoded by genes present in the mau cluster. Here we describe the sequence of the mauE and mauD genes from Paracoccus denitrificans as well as some properties of mauE and mauD mutants of this organism. The amino acid sequences derived from the mauE and mauD genes showed high similarity with their counterparts in related methylotrophs. Secondary structure analyses of the amino acid sequences predicted that MauE is a membrane protein with five transmembrane-spanning helices and that MauD is a soluble protein with an N-terminal hydrophobic tail. Sequence comparison of MauD proteins from different organisms showed that these proteins have a conserved motif, Cys-Pro-Xaa-Cys, which is similar to a conserved motif found in periplasmic proteins that are involved in the biosynthesis of bacterial periplasmic enzymes containing haem c and/or disulphide bonds. The mauE and mauD mutant strains were unable to grow on methylamine but they grew well on other C₁-compounds. These mutants grown under MADH-inducing conditions contained normal levels of the natural electron acceptor amicyanin, but undetectable levels of the -subunit and low levels of the -subunit of MADH. It is proposed, therefore, that MauE and MauD are specifically involved in the processing, transport, and/or maturation of the -subunit and that the absence of each of these proteins leads to production of a non-functional -subunit which becomes rapidly degraded.     

182 Investigating the mode of action of an essential OBG GTPase,CgtA in bacteria

CgtA is an essential OBG GTPase (Trach & Hoch, 1989) highly conserved from bacteria to eukaryotes. It is a multifunctional protein, involved in DNA replication, chromosome partitioning (Slominska et al., 2002), nutritional stress response, initiation of sporulation, ribosome maturation, etc. Despite being a multifunctional essential protein, its mode of action is not well- characterized and key question remains: how does this protein work in wide varieties of cellular function? The expression of cgtA-mRNA increases on the onset of nutritional stress. Purified CgtA protein shows increased GTPase activity in the presence of ribosome. Our experiment with thiostrepton reveals that, although ribosome is able to trigger the GTPase activity of CgtA, its probable site of GTPase inducing activity is different from other regular translation factors like EF-G, that uses GTP. For structure function study we have generated an energy minimized homology model of the Vibrio cholerae CgtA protein, which reveals two large domains, an OBG-fold and a GTP– hydrolysis domain, with an extended C-terminal part. We compared the amino acid sequence of CgtA across various species in the database, and found that its Glycine98 and the Tyrosine195 residues are 100% conserved in prokaryotes. These amino acids are highly conserved in eukaryotes as well. Gly98 and Tyr195 are located on the hinge region of CgtA comprising of portions of the OBG and the GTP–hydrolysis domains, respectively. To decipher the mode of actions of CgtA and the role of the conserved Gly98 residue, we have replaced the Gly with a relatively larger amino acid, i.e. Asp. Our study reveals that the mutant CgtA(G98D) shows a reduced GTPase activity in presence of ribosome compared to the wild type. This indicates a restricted inter-domain movement of CgtA due to the above point mutation. To understand this phenomenon we are using MD simulations. We will discuss results from MD simulations and other mutation studies as well. Our results indicate that ribosome acts as a modulator for increasing the GTPase activity of CgtA. The perfect conservation of G98 residue is important for the proper functionality of CgtA.     

Why Bacillus thuringiensis insecticidal toxins are so effective: unique features of their mode of action

The spore-forming bacterium Bacillus thuringiensis produces intracellular inclusions comprised of protoxins active on several orders of insects. These highly effective and specific toxins have great potential in agriculture and for the control of disease-related insect vectors. Inclusions ingested by larvae are solubilized and converted to active toxins in the midgut. There are two major classes, the cytolytic toxins and the delta-endotoxins. The former are produced by B. thuringiensis subspecies active on Diptera. The latter, which will be the focus of this review, are more prevalent and active on at least three orders of insects. They have a three-domain structure with extensive functional interactions among the domains. The initial reversible binding to receptors on larval midgut cells is largely dependent upon domains II and III. Subsequent steps involve toxin insertion into the membrane and aggregation, leading to the formation of gated, cation-selective channels. The channels are comprised of certain amphipathic helices in domain I, but the three processes of insertion, aggregation and the formation of functional channels are probably dependent upon all three domains. Lethality is believed to be due to destruction of the transmembrane potential, with the subsequent osmotic lysis of cells lining the midgut. In this review, the mode of action of these delta-endotoxins will be discussed with emphasis on unique features.     

葡萄休眠的自然诱导因子及其对休眠诱导期冬芽呼吸代谢的调控

以高需冷量葡萄品种‘夏黑’为试材,研究短日照、长日照和自然光照3个条件下,葡萄冬芽休眠的自然诱导因子及其对休眠诱导期冬芽呼吸代谢的调控机制.结果表明: 自然低温、短日照2个环境因素单独或共同作用均能诱导葡萄冬芽进行自然休眠.短日照在诱导葡萄冬芽进入自然休眠的过程中起主导作用,自然低温起辅助作用;温度相同条件下,日照时间越短对葡萄冬芽自然休眠的诱导作用越强.总呼吸速率达到峰值是葡萄冬芽休眠诱导期结束的标志.在自然休眠诱导期间,葡萄冬芽磷酸戊糖途径运行活性和容量占总呼吸的比例迅速上升,其中自然条件的葡萄冬芽分别由16.0%和20.1%上升至22.3%和26.0%.自然低温是诱导葡萄冬芽底物氧化水平上呼吸途径发生变化的主导因素,短日照起促进作用.在葡萄冬芽自然休眠诱导期间,交替途径运行活性和容量占总呼吸的比例迅速上升,其中自然条件葡萄冬芽分别由19.4%和27.3%上升至38.2%和46.8%.自然低温和短日照均可诱导葡萄冬芽电子传递链水平上呼吸途径发生变化.     

Cytokinins antagonize the jasmonates action on the regulation of potato (Solanum tuberosum) tuber formation in vitro

Cucurbita pepo L. (squash, pumpkin) is a highly polymorphic vegetable species of major importance. Our study characterized a spectrum of C. pepo germplasm for the ability to regenerate in vitro by direct organogenesis from cotyledon explants. Cultivars tested included both cultivated subspecies, texana and pepo, and nearly all of their respective cultivar-groups. Direct shoot regeneration occurred in all accessions, and was generally high (56–94%), with a single exception of 22% (‘Bolognese’). There was no significant difference between the percentage regeneration of the two subspecies. Shoot regeneration per responding explant was uniform (1.2–1.6 shoots per explant). Only ‘True French’ produced statistically more shoots (3.9 per explant) than other accessions. The morphology of regeneration varied. Most cultivars produced long shoots, often fasciated, amid a few small buds. Some subspecies pepo cultivars (Beirut, Yugoslavia 7, Ma’yan and True French) produced short, massive, hollow shoots, sometimes accompanied by shoots that were more normal. Two subspecies texana cultivars (Creamy Straightneck and Small Bicolor) produced single (sometimes double) shoots without other buds. The production of chimeric (mixoploid) regenerants varied and there was a tendency to regenerate chimeric plants from the widest-fruited accessions (i.e. lowest length-to-width ratio) in each subspecies. Subspecies pepo Pumpkin Group ‘Tondo di Nizza’ showed significantly greater production of chimeric regenerants. In comparison with the great range of variation observed in fruit shape, the variation of in vitro responses (mostly less than 2-fold in regeneration and shoot production) was less than expected.     

A mode of action of glucosinolate-derived isothiocyanates: Detoxification depletes glutathione and cysteine levels with ramifications on protein metabolism in Spodoptera littoralis

Glucosinolates are activated plant defenses common in the order Brassicales that release isothiocyanates (ITCs) and other hydrolysis products upon tissue damage. The reactive ITCs are toxic to insects resulting in reduced growth, delayed development and occasionally mortality. Generalist lepidopteran larvae often detoxify ingested ITCs via conjugation to glutathione (GSH) and survive on low glucosinolate diets, but it is not known how this process influences other aspects of metabolism. We investigated the impact of the aliphatic 4-methylsulfinylbutyl-ITC (4msob-ITC, sulforaphane) on the metabolism of Spodoptera littoralis larvae, which suffer a significant growth decline on 4msob-ITC-containing diets while excreting ITC-glutathione conjugates and their derivatives in the frass. The most striking effects were a decrease of GSH in midgut tissue and hemolymph due to losses by conjugation to ITC during detoxification, and a decline of the GSH biosynthetic precursor cysteine. Protein content was likewise reduced by ITC treatment suggesting that protein is actively catabolized in an attempt to supply cysteine for GSH biosynthesis. The negative growth and protein effects were relieved by dietary supplementation with cystine. Other consequences of protein breakdown included deamination of amino acids with increased excretion of uric acid and elevated lipid content. Thus metabolic detoxification of ITCs provokes a cascade of negative effects on insects that result in reduced fitness.     

The role of iron metabolism in cancer therapy focusing on tumor-associated macrophages

Iron is an essential micronutrient in mammalian cells for basic processes such as DNA synthesis, cell cycle progression, and mitochondrial activity. Macrophages play a vital role in iron metabolism, which is tightly linked to their phagocytosis of senescent and death erythrocytes. It is now recognized that the polarization process of macrophages determines the expression profile of genes associated with iron metabolism. Although iron metabolism is strictly controlled by physiology, cancer has recently been connected with disordered iron metabolism. Moreover, in the environment of cancer, tumor-associated macrophages (TAMs) exhibit an iron release phenotype, which stimulates tumor cell survival and growth. Usually, the abundance of TAMs in the tumor is implicated in poor disease prognosis. Therefore, important attention has been drawn toward the development of tumor immunotherapies targeting these TAMs focussing on iron metabolism and reprogramming polarized phenotypes. Although further systematic research is still required, these efforts are almost certainly valuable in the search for new and effective cancer treatments.