‘赛蜜酥1号’枣及其芽变品系果实的性状差异北大核心CSCD

该试验以‘赛蜜酥1号’枣及其芽变品系‘赛蜜酥2号’果实为试验材料,运用流式细胞术对它们的倍性进行鉴定,采用石蜡切片法进行果实细胞组学的观察,并对两者果实生长发育过程中的内外观品质及决定果实口感的蔗糖代谢相关酶活性进行比较分析,为深入研究芽变对枣果实口感、品质造成的影响提供理论支持。结果表明:(1)‘赛蜜酥2号’芽变品系的细胞倍性未发生改变,仍为二倍体。(2)两个枣品种(系)果实在外部形态上有明显区别,‘赛蜜酥1号’为卵圆型,‘赛蜜酥2号’为扁圆型,且后者的果形指数成熟时大于1,单果质量高于前者,核小、可食率更高,皮薄果实更加酥脆;‘赛蜜酥1号’果皮的蜡质层厚度一直大于其芽变枣,两者角质层厚度和表皮层厚度的变化趋势基本一致,但厚度之间具有显著差异。(3)影响果实细胞生长、分裂,果实脱落的各类激素水平在品种间均存在显著差异,‘赛蜜酥2号’IAA和GA_(3)含量显著高于‘赛蜜酥1号’,使之果形更大。(4)两个枣品种(系)果实可溶性糖、可滴定酸、维生素C、植物淀粉、可溶性蛋白含量等随发育时期的变化趋势一致,但含量水平之间存在差异,‘赛蜜酥2号’果实的糖含量、维生素C含量更高,可滴定酸含量更低,口感更甘甜。(5)两品种枣果实的蔗糖代谢相关酶活性在果实迅速生长的膨大期都存在着显著差异,也导致‘赛蜜酥2号’果实甜度明显高于‘赛蜜酥1号’。研究发现,两个枣品种均为二倍体,它们在果实外部形态上存在明显区别,易于分辨;芽变品系‘赛蜜酥2号’果实更大,核小、可食率更高,皮薄更加酥脆,口感更甘甜。     

基于景观生态学的城市人居环境代谢研究范式与研究框架建构

人居环境建设已经成为中国城市发展和当代生态学研究的新兴命题,基于物质代谢研究成果,系统剖析城市人居环境问题,提升城市化过程的生态文明水准成为推动新型城市化发展的重要路径选择。通过对人居环境视角和社会代谢视角的城市研究进行简要回顾,认为两种视角的有机整合可以弥补各自的理论和方法论缺陷,进而凝练出新的城市生态学研究思路。利用景观生态学理论和概念体系,建构了多层次、多维度的城市人居环境代谢研究范式和基本研究框架。这一范式可以从多尺度和多维度反映城市人居环境代谢的过程特征,厘清城市人为活动和各种资源环境问题的关联关系,整合多学科的知识和技术手段,解析城市人居环境的时空动态演化过程及其驱动机制,为城市人居环境研究学科的发展创造有利条件。通过建构基于景观生态学的城市人居环境物质能量代谢研究框架,还可以有效推进城市人居环境物质能量代谢中的格局-过程-尺度耦合问题,数据采集、储存与分析问题和效应调控与过程管理问题的研究,对于完善城市代谢研究方法,促进城市人居环境建设具有重要的参考和借鉴意义。     

Pair-housing of male and female rats during chronic stress exposure results in gender-specific behavioral responses

Social support has a positive influence on the course of a depression and social housing of rats could provide an animal model for studying the neurobiological mechanisms of social support. Male and female rats were subjected to chronic footshock stress for 3 weeks and pair-housing of rats was used to mimic social support. Rats were isolated or housed with a partner of the opposite sex. A plastic tube was placed in each cage and subsequently used as a 'safe' area in an open field test. Time spent in the tube was used as a measurement of anxiety levels. Chronic stress increased adrenal weights in all groups, except for isolated females who showed adrenal hypertrophy in control conditions. In isolated males, chronic stress resulted in an increase in the time the animals spent in the tube. While stress did not affect this parameter in socially housed males, males with a stressed partner showed a similar response as isolated stressed males. Even though adrenal weights showed that isolated females were more affected by stress, after chronic stress exposure, they spent less time in the tube than socially housed females. Socially housed stressed females spent less time in the 'safe' tube compared to control counterparts, indicating that stress has a gender-specific behavioral effect. In conclusion: pair-housing had a stress-reducing effect on behavior in males. Isolation of females was stressful by itself. Pair housing of females was not able to prevent stress-induced behavioral changes completely, but appeared to reduce the effects of chronic stress.     

Approaches for enhancement of N2 fixation efficiency of chickpea (Cicer arietinum L.) under limiting nitrogen conditions

Chickpea (Cicer arietinum) is an important pulse crop in many countries in the world. The symbioses between chickpea and Mesorhizobia, which fix N₂ inside the root nodules, are of particular importance for chickpea's productivity. With the aim of enhancing symbiotic efficiency in chickpea, we compared the symbiotic efficiency of C‐15, Ch‐191 and CP‐36 strains of Mesorhizobium ciceri in association with the local elite chickpea cultivar ‘Bivanij’ as well as studied the mechanism underlying the improvement of N₂ fixation efficiency. Our data revealed that C‐15 strain manifested the most efficient N₂ fixation in comparison with Ch‐191 or CP‐36. This finding was supported by higher plant productivity and expression levels of the nifHDK genes in C‐15 nodules. Nodule specific activity was significantly higher in C‐15 combination, partially as a result of higher electron allocation to N₂ versus H⁺. Interestingly, a striking difference in nodule carbon and nitrogen composition was observed. Sucrose cleavage enzymes displayed comparatively lower activity in nodules established by either Ch‐191 or CP‐36. Organic acid formation, particularly that of malate, was remarkably higher in nodules induced by C‐15 strain. As a result, the best symbiotic efficiency observed with C‐15‐induced nodules was reflected in a higher concentration of the total and several major amino metabolites, namely asparagine, glutamine, glutamate and aspartate. Collectively, our findings demonstrated that the improved efficiency in chickpea symbiotic system, established with C‐15, was associated with the enhanced capacity of organic acid formation and the activities of the key enzymes connected to the nodule carbon and nitrogen metabolism.     

Imaging Enzymes at Work: Metabolic Mapping by Enzyme Histochemistry

For the understanding of functions of proteins in biological and pathological processes, reporter molecules such as fluorescent proteins have become indispensable tools for visualizing the location of these proteins in intact animals, tissues, and cells. For enzymes, imaging their activity also provides information on their function or functions, which does not necessarily correlate with their location. Metabolic mapping enables imaging of activity of enzymes. The enzyme under study forms a reaction product that is fluorescent or colored by conversion of either a fluorogenic or chromogenic substrate or a fluorescent substrate with different spectral characteristics. Most chromogenic staining methods were developed in the latter half of the twentieth century but still find new applications in modern cell biology and pathology. Fluorescence methods have rapidly evolved during the last decade. This review critically evaluates the methods that are available at present for metabolic mapping in living animals, unfixed cryostat sections of tissues, and living cells, and refers to protocols of the methods of choice. (J Histochem Cytochem 58:481–497, 2010)     

Cholesteryl ester hydrolase activity is abolished in HSL macrophages but unchanged in macrophages lacking KIAA1363

Cholesteryl ester (CE) accumulation in macrophages represents a crucial event during foam cell formation, a hallmark of atherogenesis. Here we investigated the role of two previously described CE hydrolases, hormone-sensitive lipase (HSL) and KIAA1363, in macrophage CE hydrolysis. HSL and KIAA1363 exhibited marked differences in their abilities to hydrolyze CE, triacylglycerol (TG), diacylglycerol (DG), and 2-acetyl monoalkylglycerol ether (AcMAGE), a precursor for biosynthesis of platelet-activating factor (PAF). HSL efficiently cleaved all four substrates, whereas KIAA1363 hydrolyzed only AcMAGE. This contradicts previous studies suggesting that KIAA1363 is a neutral CE hydrolase. Macrophages of KIAA1363^−/− and wild-type mice exhibited identical neutral CE hydrolase activity, which was almost abolished in tissues and macrophages of HSL^−/− mice. Conversely, AcMAGE hydrolase activity was diminished in macrophages and some tissues of KIAA1363^−/− but unchanged in HSL^−/− mice. CE turnover was unaffected in macrophages lacking KIAA1363 and HSL, whereas cAMP-dependent cholesterol efflux was influenced by HSL but not by KIAA1363. Despite decreased CE hydrolase activities, HSL^−/− macrophages exhibited CE accumulation similar to wild-type (WT) macrophages. We conclude that additional enzymes must exist that cooperate with HSL to regulate CE levels in macrophages. KIAA1363 affects AcMAGE hydrolase activity but is of minor importance as a direct CE hydrolase in macrophages.     

Development of fluorescent substrates for microsomal epoxide hydrolase and application to inhibition studies

The microsomal epoxide hydrolase (mEH) plays a significant role in the metabolism of numerous xenobiotics. In addition, it has a potential role in sexual development and bile acid transport, and it is associated with a number of diseases such as emphysema, spontaneous abortion, eclampsia, and several forms of cancer. Toward developing chemical tools to study the biological role of mEH, we designed and synthesized a series of absorbent and fluorescent substrates. The highest activity for both rat and human mEH was obtained with the fluorescent substrate cyano(6-methoxy-naphthalen-2-yl)methyl glycidyl carbonate (11). An in vitro inhibition assay using this substrate ranked a series of known inhibitors similarly to the assay that used radioactive cis-stilbene oxide but with a greater discrimination between inhibitors. These results demonstrate that the new fluorescence-based assay is a useful tool for the discovery of structure–activity relationships among mEH inhibitors. Furthermore, this substrate could also be used for the screening chemical library with high accuracy and with a Z′ value of approximately 0.7. This new assay permits a significant decrease in labor and cost and also offers the advantage of a continuous readout. However, it should not be used with crude enzyme preparations due to interfering reactions.     

New roles for acyl-CoA-binding proteins (ACBPs) in plant development, stress responses and lipid metabolism

ACBPs are implicated in acyl-CoA trafficking in many eukaryotes and some prokaryotes. Six genes encode proteins designated as AtACBP1-AtACBP6 in the Arabidopsis thaliana ACBP family. These ACBPs are conserved in the acyl-CoA-binding domain, but vary in size from 92 amino acids (10.4 kDa) to 668 amino acids (73.1 kDa), and are subcellularly localised to different compartments in plant cells. Results from in vitro binding assays show that their corresponding recombinant proteins exhibit differential binding affinities to acyl-CoA esters and phospholipids, implying that these ACBPs may have non-redundant biological functions in vivo. By using knockout/downregulated and overexpression lines of Arabidopsis ACBPs, recent investigations have revealed that in addition to their proposed roles in phospholipid metabolism, these ACBPs can influence plant development including early embryogenesis and leaf senescence, as well as plant stress responses including heavy metal resistance, oxidative stress, freezing tolerance and pathogen resistance. In this review, recent progress on the biochemical and functional analyses of Arabidopsis ACBPs, their links to metabolic/signalling pathways, and their potential applications in development of stress tolerance are discussed.     

Metabolic flux analysis gives an insight on verapamil induced changes in central metabolism of HL-1 cells

Verapamil has been shown to inhibit glucose transport in several cell types. However, the consequences of this inhibition on central metabolism are not well known. In this study we focused on verapamil induced changes in metabolic fluxes in a murine atrial cell line (HL-1 cells). These cells were adapted to serum free conditions and incubated with 4 μM verapamil and [U-¹³C₅] glutamine. Specific extracellular metabolite uptake/production rates together with mass isotopomer fractions in alanine and glutamate were implemented into a metabolic network model to calculate metabolic flux distributions in the central metabolism. Verapamil decreased specific glucose consumption rate and glycolytic activity by 60%. Although the HL-1 cells show Warburg effect with high lactate production, verapamil treated cells completely stopped lactate production after 24 h while maintaining growth comparable to the untreated cells. Calculated fluxes in TCA cycle reactions as well as NADH/FADH₂ production rates were similar in both treated and untreated cells. This was confirmed by measurement of cell respiration. Reduction of lactate production seems to be the consequence of decreased glucose uptake due to verapamil. In case of tumors, this may have two fold effects; firstly depriving cancer cells of substrate for anaerobic glycolysis on which their growth is dependent; secondly changing pH of the tumor environment, as lactate secretion keeps the pH acidic and facilitates tumor growth. The results shown in this study may partly explain recent observations in which verapamil has been proposed to be a potential anticancer agent. Moreover, in biotechnological production using cell lines, verapamil may be used to reduce glucose uptake and lactate secretion thereby increasing protein production without introduction of genetic modifications and application of more complicated fed-batch processes.     

Comparative studies of zinc metabolism in cultured chinese hamster cells with differing metallothionein-induction capacities

Previous work in our laboratory led to the isolation of a cadmium (Cd)-resistant variant (Cd^r2C10) of the line CHO Chinese Hamster cell having a 10-fold greater resistance to the cytotoxic action of Cd²⁺ compared with the CHO cell. This resistance was attributed to an increased capacity of the Cd²⁺-resistant Cd^r2C10 subline to induce synthesis of the Cd²⁺- and Zn²⁺-binding protein(s), metallothionein(s) (MT). Evidence that Cd²⁺ behaves as an analog of the essential trace metal, Zn²⁺, especially as an inducer of MT synthesis, suggested that the Cd^r and CHO cell types could be employed to investigate cellular Zn²⁺ metabolism. In the present study, measurements were made to compare CHO and Cd^r cell types for (a) growth as a function of the level of ZnCl₂ added to the culture medium, (b) uptake and subcellular distribution of Zn²⁺, and (c) capacity to induce MT synthesis. The results of these measurements indicated that (a) both CHO and Cd^r cell types grew normally (T _d≊16–18 h) during exposures to Zn²⁺ at levels up to 100 μM added to the growth medium, but displayed abrupt growth inhibition at higher Zn²⁺ levels, (b) Cd^r cells incorporate fourfold more Zn²⁺ during a 24-h exposure to the maximal subtoxic level of Zn²⁺ and (c) the CHO cell lacks the capacity to induce MT synethesis while the Cd^r cell is proficient in this response during exposure to the maximal subtoxic Zn²⁺ level. These findings suggest that (a) the CHO and Cd^r cell systems will be useful in further studies of cellular Zn²⁺ metabolism, especially in comparisons of Zn²⁺ metabolism in the presence and absence of induction of the Zn²⁺-sequestering MT and (b) a relationship exists between cellular capacity to induce MT synthesis and capacity for cellular Zn²⁺ uptake.