蔗糖磷酸合酶功能、结构与催化机制的研究进展

蔗糖是自然界中广泛存在的一种天然产物.在植物等生命体中,蔗糖磷酸合酶(Sucrose phosphate synthase,SPS)是蔗糖合成的限速酶.SPS催化合成蔗糖-6-磷酸;蔗糖磷酸酶(Sucrose Phosphatase,SPP)进一步把蔗糖-6-磷酸上的磷酸根水解下来而形成蔗糖.近几十年来关于SPS的研究...     

Effects of medium components and light on callus induction, growth, and frond regeneration in Lemna gibba (Duckweed)

Summary Basal media, plant growth regulator type and concentration, sucrose, and light were examined for their effects on duckweed (Lemna gibba) frond proliferation, callus induction and growth, and frond regeneration. Murashige and Skoog medium proved best for callus induction and growth, while Schenk and Hildebrandt medium proved best for frond proliferation. The ability of auxin to induce callus was associated with the relative strength of the four auxins tested, with 20 or 50 μM 2,4-dichlorophenoxyacetic acid giving the highest frequency (10%) of fronds producing callus. Auxin combinations did not improve callus induction frequency. Auxin in combination with other plant growth regulators was needed for long-term callus growth; the two superior plant growth regulator combinations were 10 μM naphthaleneacetic acid, 10 μM gibberellic acid, and 2 μM benzyladenine with either 1 or 20 μM 2,4-dichlorophenoxyacetic acid. Three percent sucrose was best for callus induction and growth. Callus induction and growth required light. Callus that proliferated from each frond’s meristematic zone contained a mixture of dedifferentiated and somewhat organized cell masses. Continual callus selection was required to produce mostly dedifferentiated, slow-growing callus cell lines. Frond regeneration occurred on Schenk and Hildebrandt medium without plant growth regulators but was promoted by 1 μM benzyladenine. Callus maintained its ability to regenerate fronds for at least 10 mo. Regenerated fronds showed a slower growth rate than normal fronds and a low percentage of abnormal morphologies that reverted to normal after one or two subcultures.     

Altered expression of pyrophosphate: Fructose-6-phosphate 1-phosphotransferase affects the growth of transgenic <Emphasis Type="Italic">Arabidopsis</Emphasis> plants

Pyrophosphate: fructose-6-phosphate 1-phosphotransferase (PFP) catalyzes the reversible interconversion of fructose-6-phosphate and fructose-1,6-bisphosphate, a key step in the regulation of the metabolic flux toward glycolysis or gluconeogenesis. To examine the role of PFP in plant growth, we have generated transgenic Arabidopsis plants that either overexpress or repress Arabidopsis PFP sub-unit genes. The overexpressing lines displayed increased PFP activity and slightly faster growth relative to wild type plants, although their photosynthetic activities and the levels of metabolites appeared not to have significantly changed. In contrast, the RNAi lines showed significantly retarded growth in parallel with the reduced PFP activity. Analysis of photosynthetic activity revealed that the growth retardation phenotype of the RNAi lines was accompanied by the reduced rates of CO₂ assimilation. Microarray analysis of our transgenic plants further revealed that the altered expression of AtPFPβ affects the expression of several genes involved in diverse physiological processes. Our current data thus suggest that PFP is important in carbohydrate metabolism and other cellular processes. These authors contributed equally to this study.     

Jasmonates,New Regulators of Plant Growth and Development: Many Facts and Few Hypotheses on their Actions

Jasmonates, ubiquitous cyclopentanone compounds, are reviewed as new regulators for plant growth and development. They may complement the group of well-established “classic” phytohormones. Jasmonates influence a multiplicity of plant physiological processes by inhibition, promotion or induction. In many aspects they are similar to abscisic acid, especially in responses to stress. The review contains information on the chemical structures and metabolism of jasmonates, contributes to their biological role and describes possible mode(s) of action at the level of molecular biology and gene expression. In particular, emphasis is placed on the gene expression and accumulation of jasmonate-induced abundant polypeptides as a stress response of the plant cells. A hypothesis is attempted in which endogenous jasmonates represent an integral part of the signal transduction chain between stress signal(s) and stress response(s).     

One step closer to understanding mammalian macroautophagy initiation: Interplay of 2 HORMA architectures in the ULK1 complex

ULK1 and ATG13 assemble with RB1CC1/FIP200 and ATG101 to form a macroautophagy (hereafter autophagy) induction (ULK1) complex in higher eukaryotes. The yeast counterpart, the Atg1 complex, is comprised of Atg1 and Atg13 (ULK1 and ATG13 homologs), Atg17 (a proposed functional homolog of RB1CC1), and either the Atg101 subunit (in Schizosaccharomyces pombe) or the Atg29-Atg31 heterodimer (in Saccharomyces cerevisiae). With mutual exclusivity of, and no detectable homology between, the Atg29-Atg31 dimer and Atg101, knowledge about the roles of these proteins in autophagy induction is an important piece in the puzzle of understanding the molecular mechanism of autophagy initiation. A recent study reporting the structure of the S. pombe homolog Atg101 bound to the Atg13^HORMA domain is a notable contribution to this knowledge (see the punctum in this issue of the journal).     

Loss of PU.1: One of the Many Roads to Myeloid Leukemia

No abstract available.     

多胺在植物生长发育过程中的生理作用

多胺在植物生长发育过程中具有广泛的生理作用,如参与植物衰老进程的调控、体细胞胚发生、花芽分化、花和果 实的发育及参与各种生理胁迫反应等。本文重点综述了多胺在植物生长发育过程中生理学功能方面的研究进展,并对有关 问题进行了讨论和展望。     

Two Fission Yeast Rab7 Homologs, Ypt7 and Ypt71, Play Antagonistic Roles in the Regulation of Vacuolar Morphology

Small guanine triphosphatases (GTPases) of the Rab family are key regulators of membrane trafficking events between the various subcellular compartments in eukaryotic cells. Rab7 is a conserved protein required in the late endocytic pathway and in lysosome biogenesis. A Schizosaccharomyces pombe ( S. pombe ) homolog of Rab7, Ypt7, is necessary for trafficking from the endosome to the vacuole and for homotypic vacuole fusion. Here, we identified and characterized a second fission yeast Rab7 homolog, Ypt71. Ypt71 is localized to the vacuolar membrane. Cells deleted for ypt71 ⁺ exhibit normal growth rates and morphology. Interestingly, a ypt71 null mutant contains large vacuoles in contrast with the small fragmented vacuoles found in the ypt7 null mutant. Furthermore, the ypt71 mutation does not enhance or alleviate the temperature sensitivity or vacuole fusion defect of ypt7 Δ cells. Like ypt7 Δ cells, overexpression of ypt71 ⁺ caused fragmentation of vacuoles and inhibits vacuole fusion under hypotonic conditions. Thus, the two S. pombe Rab7 homologs act antagonistically in regulating vacuolar morphology. Analysis of a chimeric Ypt7/Ypt71 protein showed that Rab7-directed vacuole dynamics, fusion versus fission, largely depends on the medial region of the protein, including a part of RabSF3/α3-L7.     

牙本质基质蛋白1及其对骨形成的调控作用

牙本质基质蛋白1(dentin matrix protein 1,DMP1)是一种高度磷酸化的偏酸性非胶原蛋白, 属于小整合素结合配体N端连接糖蛋白（small integrin-binding ligand, N-linked glycoprotein, SIBLINGs）家族.和SIBLINGs家族其它成员一样,DMP1基因定位于人类染色体4q21除存在于牙组织外,该蛋白还普遍分布于骨组织中.在骨组织与细胞中已发现4种DMP1的主要存在形式,即全长DMP1、57 kD C-DMP1、37 kD N-DMP1、DMP1-PG.它们的分布与功能均不相同,但对骨的正常形成均有重要意义. DMP1的氨基酸序列拥有大量的酸性结构域,携带负电荷,与钙离子有较强的结合能力.它在体外能够促进羟基磷灰石形成,并调控细胞分化,在体内参与硬组织的矿化过程.另外,DMP1的水解过程对其调控矿化的功能十分关键.人体内DMP1基因的突变可导致常染色体隐性低血磷性佝偻病.本文就近几年对DMP1基因结构与调控、蛋白结构与代谢、在骨组织与细胞中的分布及其对骨形成调控作用的研究进展作一综述.     

Inhibition of inward rectifying tonoplast channels by a vacuolar factor: Physiological and kinetic implications

Summary Regulation of ion-channel activity must take place in order to regulate ion transport. In case of tonoplast ion channels, this is possible on both the cytoplasmic and the vacuolar side. Isolated vacuoles of youngVigna unguiculata seedlings show no or hardly any channel activity at tonoplast potentials >80 mV, in the vacuole-attached configuration. When the configuration is changed to an excised patch or whole vacuole, a fast (excised patch) or slow (whole vacuole) increase of inward rectifying channel activity is seen. This increase is accompanied by a shift in the voltage-dependent gating to less hyperpolarized potentials. In the whole vacuole configuration the level of inward current increases and also the activation kinetics changes. Induction of channel activity takes up to 20 min depending on the age of the plants used and the diameter of the vacuole. On the basis of the estimated diffusion velocities, it is hypothesized that a compound with a mol wt of 20,000 to 200,000 is present in vacuoles of young seedlings, which shifts the population of channels to a less voltage-sensitive state.Ecotrans publication no. 27.     

The Physiological,Biochemical and Molecular Roles of Brassinosteroids and Salicylic Acid in Plant Processes and Salt Tolerance

Plant hormones regulate plant growth and development by affecting an array of cellular, physiological, and developmental processes, including, but not limited to, cell division and elongation, stomatal regulation, photosynthesis, transpiration, ion uptake and transport, initiation of leaf, flower and fruit development, and senescence. Environmental factors such as salinity, drought, and extreme temperatures may cause a reduction in plant growth and productivity by altering the endogenous levels of plant hormones, sensitivity to plant hormones, and/or signaling pathways. Molecular and physiological studies have determined that plant hormones and abiotic stresses have interactive effects on a number of basic biochemical and physiological processes, leading to reduced plant growth and development. Various strategies have been considered or employed to maximize plant growth and productivity under environmental stresses such as salt-stress. A fundamental approach is to develop salt-tolerant plants through genetic means. Breeding for salt tolerance, however, is a long-term endeavor with its own complexities and inherent difficulties. The success of this approach depends, among others, on the availability of genetic sources of tolerance and reliable screening techniques, identification and successful transfer of genetic components of tolerance to desired genetic backgrounds, and development of elite breeding lines and cultivars with salt tolerance and other desirable agricultural characteristics. Such extensive processes have delayed development of successful salt-tolerant cultivars in most crop species. An alternative and technically simpler approach is to induce salt tolerance through exogenous application of certain plant growth–regulating compounds. This approach has gained significant interest during the past decade, when a wealth of new knowledge has become available on the beneficial roles of the six classes of plant hormones (auxins, gibberellins, cytokinins, abscisic acid, ethylene, and brassinosteroids) as well as several other plant growth–regulating substances (jasmonates, salicylates, polyamines, triacontanol, ascorbic acid, and tocopherols) on plant stress tolerance. Among these, brassinosteroids (BRs) and salicylic acid (SA) have been studied most extensively. Both BRs and SA are ubiquitous in the plant kingdom, affecting plant growth and development in many different ways, and are known to improve plant stress tolerance. In this article, we review and discuss the current knowledge and possible applications of BRs and SA that could be used to mitigate the harmful effects of salt-stress in plants. We also discuss the roles of exogenous applications of BRs and SA in the regulation of various biochemical and physiological processes leading to improved salt tolerance in plants.     

Anaerobic promotion of stem extension in Potamogeton pectinatus. Roles for carbon dioxide, acidification and hormones

Dark-grown shoots of tubers of the aquatic monocot Potamogön pectinatus L. elongated more strongly in anaerobic than aerobic solutions over 5 days. The response was located in the stem rather than the leaf. Anaerobic carbon dioxide (CO₂) production was similar to that in aerobic conditions. Approximately half the anaerobic stem extension was attributed to acidification of the submerging medium by respiratory CO₂. Sparging with an anaerobic gas mixture of nitrogen and hydrogen to remove dissolved CO₂ inhibited stem elongation and prevented acidification of the medium. Similarly, supplying CO₂ anaerobically promoted stem elongation while acidifying the medium. Carbon dioxide was also active on aerobic shoots. The effect of CO₂ on anaerobic stem extension could be mimicked with an acidic buffer. Anaerobic stem extension was inhibited by exogenous abscisic acid (ABA), while gibberellic acid and the gibberellin-biosynthesis inhibitor paclobutrazol proved inactive. Exogenous indole-3-acetic acid promoted stem extension in the absence of oxygen. A strong gravitropic response by anaerobic stems of P. pectinatus was inhibited by the auxin-efflux inhibitor naphthylphthalamic acid.     

Plasmodium falciparum Exported Protein 1 is localized to dense granules in merozoites

Apical organellar proteins in Plasmodium falciparum merozoites play important roles upon invasion. To date, dense granule, the least studied apical organelle, secretes parasite proteins across the parasitophorous vacuole membrane (PVM) to remodel the infected erythrocyte. Although this phenomenon is key to parasite growth and virulence, only five proteins so far have been identified as dense granule proteins. Further elucidation of dense granule molecule(s) is therefore required. P. falciparum Exported Protein (EXP) 1, previously reported as a parasitophorous vacuole membrane (PVM) protein, is considered essential for parasite growth. In this study, we characterized EXP1 using specific anti-EXP1 antibodies generated by immunization of wheat germ cell-free produced recombinant EXP1. Immunofluorescence microscopy (IFA) demonstrated that EXP1 co-localized with RESA, indicating that the protein is initially localized to dense granules in merozoites, followed by translocation to the PVM. The EXP1 localization in dense granule of merozoites and its translocation to the PVM after invasion of erythrocytes were further confirmed by immunoelectron microscopy. Here, we demonstrate that EXP1 is one of the dense granule proteins in merozoites, which is then transported to the PVM after invasion.     

Protein transport across the parasitophorous vacuole of Plasmodium falciparum: into the great wide open

The human malaria parasite Plasmodium falciparum resides and multiplies within a membrane-bound vacuole in the cytosol of its host cell, the mature human erythrocyte. To enable the parasite to complete its intraerythrocytic life cycle, a large number of parasite proteins are synthesized and transported from the parasite to the infected cell. To gain access to the erythrocyte, parasite proteins must first cross the membrane of the parasitophorous vacuole (PVM), a process that is not well understood at the mechanistic level. Here, we review past and current literature on this topic, and make tentative predictions about the nature of the transport machinery required for transport of proteins across the PVM, and the molecular factors involved.     

Proton-driven sucrose symport and antiport are provided by the vacuolar transporters SUC4 and TMT1/2

The vacuolar membrane is involved in solute uptake into and release from the vacuole, which is the largest plant organelle. In addition to inorganic ions and metabolites, large quantities of protons and sugars are shuttled across this membrane. Current models suggest that the proton gradient across the membrane drives the accumulation and/or release of sugars. Recent studies have associated AtSUC4 with the vacuolar membrane. Some members of the SUC family are plasma membrane proton/sucrose symporters. In addition, the sugar transporters TMT1 and TMT2, which are localized to the vacuolar membrane, have been suggested to function in proton-driven glucose antiport. Here we used the patch-clamp technique to monitor carrier-mediated sucrose transport by AtSUC4 and AtTMTs in intact Arabidopsis thaliana mesophyll vacuoles. In the whole-vacuole configuration with wild-type material, cytosolic sucrose-induced proton currents were associated with a proton/sucrose antiport mechanism. To identify the related transporter on one hand, and to enable the recording of symporter-mediated currents on the other hand, we electrophysiologically characterized vacuolar proteins recognized by Arabidopsis mutants of partially impaired sugar compartmentation. To our surprise, the intrinsic sucrose/proton antiporter activity was greatly reduced when vacuoles were isolated from plants lacking the monosaccharide transporter AtTMT1/TMT2. Transient expression of AtSUC4 in this mutant background resulted in proton/sucrose symport activity. From these studies, we conclude that, in the natural environment within the Arabidopsis cell, AtSUC4 most likely catalyses proton-coupled sucrose export from the vacuole. However, TMT1/2 probably represents a proton-coupled antiporter capable of high-capacity loading of glucose and sucrose into the vacuole.     

Photosynthesis, reserve mobilization and enzymes of sucrose metabolism in soybean (Glycine max) cotyledons

Soybean (Glycine max L. [Merr] cv. Ransom II) seedlings were grown under a light/ dark regime or in continuous darkness. Cotyledons were harvested daily for measurements of reserve mobilization, net carbon exchange rate, chlorophyll content and activities of certain enzymes involved in sucrose metabolism. Seedlings lost dry weight for the first 3 to 4 days after planting, then maintained a constant dry weight in the etiolated seedlings, and gained dry weight (via net fixation of CO₂) in the light-grown seedlings. In general, the patterns of reserve mobilization were as expected based on the collective work of other investigators. Soluble sugars were mobilized first, followed by protein and lipid. Galactinol, previously uncharacterized in soybean cotyledons, was present at low concentrations and was rapidly depleted within 2 days after planting. Mobilization of reserves was most important during the first 8 days after planting, whereas net cotyledonary photosynthesis began at 6 days after planting and was the primary source of assimilates after 8 days. Maximum rates of cotyledon photosynthesis were higher [up to 18 mg CO₂ (g dry weight)^?1 h^?1] than previously reported and accounted for about 75% of the assimilates transported from the cotyledons to the growing seedling during the functional life of the cotyledon. Enzyme activities in light-grown cotyledons peaked 7 to 10 days after planting and then declined. Sucrose phosphate synthase (EC 2.4.1.14) and sucrose synthase (EC 2.4.1.13) activities were similar in etiolated and light-grown seedlings, whereas uridine-5′-di-phosphatase (EC 3.6.1.6) activity was substantially higher in light-grown seedlings. During the period of reserve mobilization, the maximum sucrose phosphate synthase activity in cotyledonary extracts was in excess of the calculated rate of sucrose formation. However, when the cotyledons had highest net photosynthetic rates (14 days after planting), sucrose phosphate synthase activity was similar to the rate of carbon assimilation. It appears that soybean cotyledons are adapted for high rates of sucrose formation (from reserve mobilization and/or photosynthesis) for export to the rapidly growing tissues of the seedling.