禾谷类作物淀粉合酶

淀粉合酶是禾谷类作物淀粉合成所必需的一类酶.根据淀粉合酶家族成员的氨基酸序列的相似性,分别介绍了一个颗粒性淀粉合酶亚家族和四个可溶淀粉合酶亚家族的组成、基因结构和表达特点,并从转录、转录后和翻译后水平上对这些基因的表达调控做了概述.     

水稻叶片淀粉的分离与理化性质分析

目的 分离高质量的叶片淀粉有助于研究叶片淀粉的理化特性及发育调控机制。利用已报道的叶片淀粉提取方法分离水稻叶片淀粉;步骤繁琐;操作要求高;且分离的水稻叶片淀粉纯度不高。因此;需要建立一种适合水稻叶片淀粉提取的方法。 方法 优化获得一种操作简单的水稻叶片淀粉分离和纯化方法;主要包括叶片磨粉、细胞裂解、淀粉释放、过筛、杂质去除、静置沉降、水洗淀粉、乙醇脱水和烘干保存9个步骤。该方法改良的核心在于利用静置沉降替代拟南芥叶片淀粉提取方法中的离心收集淀粉;通过3次悬浮沉降即可有效分离水稻叶片淀粉。 结果 利用该方法分离纯化3种水稻叶片的淀粉;经测定沉淀中淀粉纯度可以达到87%。与多角形的水稻胚乳淀粉粒形态相比;水稻叶片淀粉粒呈现扁平状和长的椭球形;且淀粉粒显著小于胚乳淀粉粒。热力学特性分析显示水稻叶片淀粉的糊化起始温度、峰值温度和终止温度显著高于胚乳淀粉;而热焓值低于胚乳淀粉。 结论 优化的叶片淀粉分离和提纯方法操作过程简单并且环保;获得的高纯度水稻叶片淀粉可以用于淀粉形态和理化特性的研究。     

大革耳子实体多糖抗氧化活性

作者对大革耳子实体多糖的抗氧化能力及单糖组分进行了分析,并探究了大革耳子实体多糖体外对羟自由基、超氧阴离子自由基、1,1-二苯基-2-三硝基苯肼（1,1-diphenyl-2-picrylhydrazyl,DPPH）自由基、2'-联氨-双-3-乙基苯并噻唑啉-6-磺酸[2,2'-azino-bis (3-ethylbenzothiazoline-6-sulfonic acid),ABTS]自由基的清除能力和铁离子还原能力;以人正常肝细胞系LO2为材料建立了过氧化氢细胞氧化损伤模型,并探讨大革耳子实体多糖在细胞水平的抗氧化能力;通过苯酚硫酸法及HPLC检测了子实体多糖的单糖含量及组分。体外化学抗氧化实验结果显示,大革耳子实体多糖对羟自由基、超氧阴离子、DPPH自由基和ABTS自由基的清除能力较强,且具有较高的铁离子还原能力;细胞水平抗氧化实验表明,大革耳子实体多糖对人正常肝细胞系LO2的H₂O₂氧化损伤具有显著的保护作用,并能极显著提高受损细胞内过氧化氢酶（catalase,CAT）（P<0.01）及超氧化物歧化酶（superoxide dismutase,SOD）（P<0.01）的活力。大革耳子实体活性多糖主要单糖含量及组分依次为：葡萄糖（2 985.50mg/kg）、甘露糖（1 867.23mg/kg）、木糖（814.98mg/kg）、半乳糖（724.24mg/kg）、岩藻糖（443.72mg/kg）、葡萄糖醛酸（419.41mg/kg）、鼠李糖（81.18mg/kg）、阿拉伯糖（64.40mg/kg）、核糖（39.95mg/kg）、半乳糖醛酸（24.40mg/kg）。本研究结果为更好的推广应用和科学开发大革耳提供了基础资料。     

5个不同灵芝种菌丝体多糖理化性质及免疫活性研究

对灵芝属G.lucidum,G.tsugae,G.oerstedii,G.resinaceum,G.subamboinens5个不同种用同一条件进行了液体发酵培养、多糖提取、理化性质及免疫活性的分析。结果表明,5种灵芝的菌丝体多糖得率相差较大,以G.oerstedii最高,但各多糖提取物分子量分布相似,单糖组成均以葡萄糖为主,并含半乳糖、甘露糖、盐酸氨基葡萄糖、岩藻糖。5种多糖提取物均能显著增强小鼠巨噬细胞Raw264.7吞噬作用、释放NO,但以G.subamboinens菌丝体多糖提取物的活性最强。这些多糖提取物还均能促进小鼠脾细胞的增殖,并对ConA诱导的淋巴细胞增殖有抑制作用。研究表明灵芝属内其他3个物种的菌丝体多糖提取物理化特征与G.lucidum和G.tsugae接近,并同样具有免疫调节作用。     

海藻多糖的单糖组成对体外抗氧化活性的影响

比较广西北部湾石莼(Ulva lactuca L.)、海带(Laminaria japonica)、裙带菜(Undaria pinnatifida Surin-gar)、紫菜(Porphyra)的单糖组成及抗氧化活性的差异,揭示多糖结构与其体外抗氧化活性的关系。利用PMP柱前衍生化HPLC分析海藻多糖的单糖组成,采用羟自由基清除试验、超氧阴离子自由基清除试验及DPPH自由基清除试验指征其体外抗氧化活性,结果表明,4种海藻多糖的单糖组成在主成分空间分布离散,石莼及紫菜主要由葡萄糖组成,海带主要由甘露糖组成,裙带菜则主要由半乳糖组成;其体外抗氧化活性存在显著差异,裙带菜多糖对DPPH的清除能力(半抑制浓度IC₅₀值为0. 56±0. 02 mg/mL)显著高于其他3种海藻多糖;石莼、裙带菜与海带对羟自由基均有较强的清除活性,而紫菜多糖对羟自由基的清除能力较差(IC₅₀值为26. 59±0. 98mg/mL);石莼与裙带菜对超氧阴离子的清除活性较强,显著高于海带与紫菜,其中石莼显著高于裙带菜,IC₅₀值分别为1. 61±0. 17、2. 73±0. 06 mg/mL。相关性分析及冗余分析结果表明,对抗氧化活性影响较为显著的因子为葡萄糖(Glc)、核糖(Rib)、木糖(Xyl)(P <0. 01)。     

淫羊藿多糖的分离纯化及结构初步分析

从淫羊藿中提取多糖并鉴定其初步结构和单糖组成.采用超声-水提醇沉法提取粗多糖、Sevag法去蛋白、DEAE-52纤维素及Sephadex G-100柱层析法纯化得到淫羊藿多糖EPSⅠ-1和EPSⅡ-1.应用紫外光谱法和红外光谱法对其结构做初步分析.采用高效液相色谱法(HPLC)测定其单糖组成及摩尔比.均一的EPSⅠ-1和EPSⅡ-1多糖在紫外和红外中具有多糖的特征吸收峰,组成中含有吡喃环结构;EPSⅠ-1的单糖组成为鼠李糖和葡萄糖,摩尔比为1:1.13;EPSⅡ-1的单糖组成为果糖、葡萄糖和一个不确定的糖,摩尔比为1:1.91.有效地分离纯化了淫羊藿多糖,这为淫羊藿多糖的广泛应用奠定了实验基础.     

小麦花后弱光引起籽粒淀粉的粒度分布及组分含量的变化

在籽粒灌浆阶段(花后1～30 d)对小麦进行光强为自然光照45%的弱光处理,研究了小麦籽粒淀粉粒度分布和组分含量的变化.结果表明,小麦籽粒淀粉粒体积分布呈双峰曲线,峰值分别在5.1～6.1 μm和20.7～24.9 μm,两峰值间的低谷出现在9.9 μm左右.表面积分布和数目分布分别表现为双峰和单峰曲线.小麦花后弱光显著降低2.8～9.9 μm淀粉粒体积百分比,增加22.8～42.8 μm淀粉粒体积百分比.同时花后弱光显著降低<0.8 μm和2.8～9.8 μm淀粉粒表面积百分比,增加0.8～2.8 μm和>9.9 μm淀粉粒表面积百分比.可见灌浆期弱光显著降低籽粒B型(＜9.9 μm)淀粉粒体积和表面积百分比,而A型(＞9.9 μm)淀粉粒比例相对增加.与A型淀粉粒相比,B型淀粉粒对弱光的反映更敏感.小麦弱光处理籽粒淀粉及其组分含量显著低于对照,但其直/支比较对照高.相关分析表明,籽粒直/支比与2.8～9.9 μm淀粉粒体积百分比呈显著负相关,而与22.8～42.8 μm淀粉粒体积百分比呈显著正相关.花后不同阶段弱光显著增加A型淀粉粒体积百分比、降低B型淀粉粒体积百分比,其中灌浆中、后期弱光影响程度较前期大.表明,弱光条件下小麦籽粒淀粉合成底物优先供应淀粉粒的生长,而非形成更多的淀粉粒.     

花后高温对持绿型小麦叶片衰老及籽粒淀粉合成相关酶的影响

试验选用持绿型冬小麦(Triticum aestivum) ‘豫麦66’ (‘Ym66’)和‘潍麦8号’ (‘Wm8’)为研究材料, 以当地生产上起主导作用的冬小麦品种‘小偃22’ (‘XY22’)和‘小偃6号’ (‘XY6’)为对照。花后用塑料薄膜搭建成增温棚进行高温处理, 测定各品种绿叶数目、叶绿素和丙二醛(MDA)含量及叶片细胞膜透性, 并研究籽粒灌浆成熟期高温对持绿型小麦籽粒淀粉合成相关酶及粒重的影响。结果表明, 高温处理后, 各品种的绿叶数目和叶绿素含量都减少, MDA含量和膜透性都增加, 说明高温加速了小麦叶片衰老。同时, 各品种籽粒中与淀粉合成相关的酶(蔗糖合成酶(SS)和腺苷二磷酸葡萄糖焦磷酸化酶(AGPP)、可溶性淀粉合酶(SSS))活性都低于正常生长下的籽粒中的酶活性, 其中高温对籽粒SS和AGPP活性的影响不显著,而对籽粒SSS活性的影响显著(p = 0.015)。品种间比较, 持绿型小麦在两种处理下, 都表现出较多的绿叶数目和较高的叶绿素含量; 且3种与淀粉合成相关的酶活性也都高于非持绿型小麦, 说明持绿型小麦酶活性受高温抑制程度较小。相关性分析表明, 所有品种籽粒SS、AGPP、SSS活性都与籽粒灌浆速率成极显著的正相关(相关系数r分别为0.905、0.419和0.801)。因而, 持绿型小麦不仅具有较好的持绿特性, 而且籽粒中与淀粉合成相关的3种酶活性都较高, 这有利于其籽粒淀粉的合成, 从而增加籽粒产量。     

NOTE—THE STA-1 MUTATION PREVENTS ASSEMBLY OF STARCH GRANULES IN NITROGEN-STARVED CELLS AND SERVES AS A USEFUL MORPHOLOGICAL MARKER DURING SEXUAL REPRODUCTION IN CHLAMYDOMONAS MONOICA (CHLOROPHYCEAE)

Iodine staining of clones of nitrogen-starved Chlamydomonas cells was used to screen for mutants with altered levels or altered composition of storage starch. Mutations leading to defects in quantity or morphology of starch granules not only can provide information on storage starch biosynthesis and granule assembly but can also be used as morphological markers in genetic and cell biological studies. A mutant of Chlamydomonas monoica Strehlow devoid of starch granules was obtained following ultraviolet mutagenesis. Nitrogen-starved cells of the sta-1 strain lacked pyrenoidal starch granules and granules normally associated with thylakoid membranes. The mutant phenotype was the consequence of a single Mendelian mutation that appeared to affect granule assembly rather than starch biosynthesis per se and that had no effect on vegetative growth, sexual reproduction, or zygospore viability.     

银耳多糖单糖组成分析的三种色谱方法比较

为选择一种准确快捷的方法测定银耳多糖的单糖组成,对薄层色谱法(TLC)、气相色谱法(GC)、高效液相色谱法(HPLC)三种色谱方法进行比较。结果表明,前两种方法的测定结果均不理想,而HPLC法,操作简便,灵敏度高,分离效果好,信息完整。测定结果为由葡萄糖、甘露糖、葡萄糖醛酸、木糖、岩藻糖组成,其摩尔比为0.24∶1.00∶0.06∶0.29∶0.25。HPLC法对酸性杂多糖组成糖分析是一种比较理想的选择。     

Polysaccharide analysis using carbohydrate gel electrophoresis: a method to study plant cell wall polysaccharides and polysaccharide hydrolases.

A method to characterize plant cell wall polysaccharides is presented. The complexity of the polymer structures and the large number of different charged and uncharged monosaccharides that make up plant polysaccharides have previously made analysis technically demanding and laborious. Polysaccharide analysis using carbohydrate gel electrophoresis (PACE) relies on derivatization of reducing ends of sugars and oligosaccharides with a fluorophore, followed by electrophoresis under optimized conditions in polyacrylamide gels. We show that PACE is a sensitive and simple tool for studying the monosaccharide composition of polysaccharides and of cell wall preparations. In combination with specific hydrolases, it can be used to analyze the structure of polysaccharides. Moreover, the specificity and kinetics of the plant polysaccharide hydrolases themselves can be quickly and effectively studied. PACE can detect as little as 500 fmol of monosaccharides and 100 fmol of oligosaccharides, and it is fast and quantitative.     

苦瓜多糖的提取、分离纯化及组成性质

正交实验确定提取工艺后,用热水提取法得到苦瓜多糖(MCP).对MCP进行DEAE-32离子交换层析分离,得到3个多糖组分MCP1、MCP2和MCP3. 进一步采用Sephacryl S-400凝胶层析进行分离,经凝胶层析和高效液相色谱检测表明,MCP1、MCP2为均一性多糖组分.通过高效液相凝胶色谱法测定了两者的相对分子质量分别为1.16×106和7.45×105.用PMP衍生化法测定其单糖,结果表明: MCP1系由Man、Rham、GlcUA、GalUA、Glu、Gal、Xyl、Ara等单糖组成的杂多糖,摩尔比为1.03:2.93:1.00:14.95:2.16:30.70:2.85:4.50.MCP2系由Rham、GalUA、Gal、Xyl、Ara等单糖组成的杂多糖,对应的摩尔比为1.63:21.88:4.66:1.00:1.29.紫外光谱表明该多糖不含蛋白质和核酸.     

ADP-Glucose Pyrophosphorylase: A Regulatory Enzyme for Plant Starch Synthesis

In plants, the synthesis of starch occurs by utilizing ADP-glucose as the glucosyl donor for the elongation of alpha-1,4-glucosidic chains. In photosynthetic bacteria the synthesis of glycogen follows a similar pathway. The first committed step in these pathways is the synthesis of ADP-glucose in a reaction catalyzed by ADP-glucose pyrophosphorylase (ADPGlc PPase). Generally, this enzyme is allosterically regulated by intermediates of the major carbon assimilatory pathway in the respective organism. In oxygenic photosynthesizers, ADPGlc PPase is mainly regulated by 3-phosphoglycerate (activator) and inorganic orthophosphate (inhibitor), interacting in four different patterns. Recent reports have shown that in higher plants, some of the enzymes could also be redox regulated. In eukaryotes, the enzyme is a heterotetramer comprised of two distinct subunits, a catalytic and a modulatory subunit. The latter has been proposed as related to variations in regulation of the enzyme in different plant tissues. Random and site-directed mutagenesis experiments of conserved amino acids revealed important residues for catalysis and regulation. Prediction of the ADPGlc PPase secondary structure suggests that it shares a common folding pattern to other sugar-nucleotide pyrophosphorylases, and they evolved from a common ancestor.     

Urea-hydrolysis-dependent citrulline synthesis by Ureaplasma urealyticum

Some of the ammonia produced by hydrolysis of urea by Ureaplasma urealyticum is channelled into an anabolic pathway with resultant 'de novo' synthesis of citrulline. The organism appears to possess ornithine carbamoyltransferase and carbamoyl phosphate synthetase or some modified form of these enzymes.     

Effects of protein on crosslinking of normal maize, waxy maize, and potato starches

Channels of maize starch granules are lined with proteins and phospholipids. Therefore, when they are treated with reagents that react at or near the surfaces of channels, three types of crosslinks could be produced: protein–protein, protein–starch, starch–starch. To determine which of these may be occurring and the effect(s) of channel proteins (and their removal) on crosslinking, normal and waxy maize starches were treated with a proteinase (thermolysin, which is known to remove protein from channels) before and after crosslinking, and the properties of the products were compared to those of a control (crosslinking without proteinase treatment). After establishing that treatment of starch with thermolysin alone had no effect on the RVA trace, three reaction sequences were used: crosslinking alone (CL), proteinase treatment before crosslinking (Enz-CL), proteinase treatment after crosslinking (CL-Enz). Two crosslinking reagents were used: phosphoryl chloride (POCl₃), which is known to react at or near channel surfaces; STMP, which is believed to react throughout the granule matrix. Three concentrations of POCl₃ (based on the weight of starch) were used. For both normal maize starch (NMS) and waxy maize starch (WMS) reacted with POCl₃, the trends were generally the same, with apparent relative degrees of crosslinking indicated to be CL-Enz = CL > Enz-CL, but the effects were greater with NMS and there were differences when different concentrations of reagent were used. The basic trends were the same when potato starch was used in the same experiments. Crosslinking with STMP was done both in the presence and the absence of sodium sulfate (SS). Both with and without SS and with both NMS and WMS, the order of indicated crosslinking was generally the same as found after reaction with POCl₃, with the indicated swelling inhibition being greater when SS was present in the reaction mixture. Examination of the maize starches with a protein stain indicated that channel protein was removed by treatment with thermolysin when the proteinase treatment occurred before crosslinking with either POCl₃ or STMP, but only incompletely or not at all if the treatment with the proteinase occurred after crosslinking. Because the crosslinking reactions were less effective when the protein was removed, the results are tentatively interpreted as indicating that they involved protein molecules, although there may not be a direct relationship.     

魔芋球茎贮藏淀粉和甘露聚糖粒的形态观察

在光学显微镜和透射电镜下观察了魔芋（Ａｍｏｒｐｈｏｐｈａｌｕｓｃｏｎｊａｃ）球茎中甘露聚糖粒和淀粉粒的形态。两种贮藏多糖分别位于不同的细胞中。淀粉粒在造粉体内发育,以复粒存在,用魔芋球茎仔茎茎尖为材料观察显示,淀粉粒的形成早于甘露聚糖颗粒的形成。甘露聚糖粒形态多数近随圆形,一些甘露聚糖颗粒内包含了针晶体,但多数的甘露聚糖粒内部不包含针晶体,由纯净的甘露聚糖构成。     

豆皮水溶性多糖组分SHP-3的物化性质研究(英文)

对豆皮采用热水浸提得到豆皮水溶性多糖,通过DEAE-cellulose离子交换柱洗脱,得到3个组分。本文主要研究了采用0.3 M NaOH溶液洗脱纯化得到的组分SHP-3的物化性质。对SHP-3进行凝胶渗透色谱、气相色谱分析、紫外光谱及高碘酸氧化-Smith降解分析,结果表明:SHP-3的分子量为45554,其糖醛酸含量为26.71%(wt.%),单糖组成摩尔比为Rah:Fuc:Ara:Xyl:Man:Gal:Glu=3.55:0.44:11.58:1:7.45:5.12:1.12,紫外光谱在260～280 nm没有吸收峰,表明没有蛋白质或核酸等物质;高碘酸氧化-Smith降解结果表明SHP-3的连接结构以为(1→4)糖苷键为主,其摩尔比例占68.9%,(1→2)糖苷键占11.4%,(1→6)糖苷键占19.7%。     

猪链球菌1、2、14、1/2型荚膜多糖的单糖组成比较

【目的】猪链球菌1、2、14和1/2型间存在单向或双向的交叉抗原性,这种交叉抗原性的产生原因至今未被揭示。【方法】采用Sephacryl S-300凝胶层析柱对猪链球菌14和1/2型荚膜多糖进行分离纯化,经苯酚-硫酸检测和dot-ELISA辅助鉴定,确定荚膜多糖成分。采用高效凝胶渗透色谱法测定14和1/2型猪链球菌荚膜多糖分子量分别为487.38 kDa和512.72 kDa。【结果】经柱前衍生高效液相色谱法、荧光标记液相色谱法和核磁共振测定14和1/2型猪链球菌荚膜多糖单糖组成分别为:Glc/Gal/GlcNAc/Rha/Neu5Ac(1∶2.94∶1.35∶0.24∶0.37)和Glc/Gal/GlcNAc/GalNAc/Rha/Neu5Ac(1∶1.67∶1.05∶0.93∶0.72∶0.7)。并与已知的猪链球菌1、2型荚膜多糖的单糖组成进行比较分析,发现4种血清型荚膜多糖都具有Glc、GlcNAc、Gal和Neu5Ac,但单糖组成和比列并无明显相似性,这种交叉抗原性可能是由于荚膜多糖的空间结构相似性和(或)细胞表面的其他成分引起的。