1,6-二磷酸果糖与细胞保护

1,6-二磷酸果糖是细胞内糖代谢的中间产物,是能在分子水平上调节细胞代谢中若干酶活性,作为恢复和改善细胞代谢的药物,可通过多方面因素减轻细胞损伤,从而对细胞起保护作用。     

蛇肌果糖1,6—二磷酸酯酶,果糖2,6—二磷酸,AMP的结…

腺苷一磷酸对４个快反应巯基被修饰的蛇肌果糖１,６－二磷酸酯酶活性的抑制作用增强,而该修饰的酶受果糖２,６－二磷酸的抑制脱敏,ＡＭＰ对酶抑制为半部位反应,酶受果糖２,６－二磷酸抑制的脱敏则表现为全部位反应,经枯草杆菌蛋白酶限制性酶解的果糖１,６－二磷酸酯酶的Ｋ１增大１０倍,但受果糖２,６－二磷酸抑制的性质不变,经胰蛋白酶限制性酶解的果糖１,６－二磷酸酯酶的活性不再为ＡＭＰ抑制,但果糖２,６－二磷酸对     

固定化酵母细胞生产1,6—二磷酸果糖研究

本文研究了固定化酵母细胞制备果糖１,６二磷酸的方法及其生产。用卡拉胶包埋方法固定化酿酒酵母,对含葡萄糖１．０Ｍ,磷酸盐０．８Ｍ的糖磷液,ＰＨ６．５在３７℃下进行磷酸化反应。反复分批转化２０天以上,可达到平均产ＦＤＰＨ４ ２７．５８ｍｇ／ｍｌ。最高为５９．９４ｍｇ／ｍｌ。     

丝状真菌转化葡萄糖为果糖-1,6-二磷酸的研究

STUDYONTHEBIOCONVERSIONOFGLUCOSETOFRUCTOSE-1,6-DIPHOSPHATEWITHFILAMENTOUSFUNGICELLMOXiao-Yan;ZHANGu-Yu;XIANGYuHong(DepartmentofBiotechnology,XianJiaotongUniversity,Xian7l0049)80至90年代发现果糖一l,6一二磷酸（Fructose－l,6－diphosphateFDP）在医药、保健品和植物生长调节方面的诸多用途,尤其用于医药备受关注。传统FDP的生产是用面包酵母或啤酒酵母作酶源,通过糖酵解过程而获得（Leisolaetal,1974）,以后有用固定化酵母细胞、固相化多酶系统及嗜热脂肪芽胞杆菌转化葡…     

固定化酵母细胞生产1,6-二磷酸果糖研究

本文研究了固定化酵母细胞制备果糖1,6二磷酸(FDP)的方法及其生产。用卡拉胶包埋方法固定化酿酒酵母(Sacchromyces cerevisae),对含葡萄糖1.0M,磷酸盐0.8M的糖磷液,pH6.5,在37℃下进行磷酸化反应。反复分批转化20天以上,可达到平均产FDPH_427.58mg/ml,最高为59.94mg/ml。用100ml固定化细胞生物反应器连续运转309h,稀释速率D=0.097h~(-1),平均产FDPH_4 21.51mg/ml。20L反应器连续运转,生产能力达到1.7g/h.L。用层析方法制备FDPNa_3结晶粉,提取收率为72.08％,制备质量达到或超过了国内外同类产品的质量要求。     

1,6-二磷酸果糖的研究进展

１,６—二磷酸果糖（ＦＤＰ）是糖酵解过程中的代谢产物,具有调节糖代谢中若干酶活性之功效,为恢复、改善细胞代谢的分子水平药物。由Ｈａｒｄｅｎ和Ｙｏｕｎｇ［１］于１９０８年首先发现并阐明了一般特性。其后,美国、德国、意大利、日本、芬兰等国的学者分别对ＦＤＰ的制备和应用作了深入而富有成效的研究。［２］［３］［４］［５］１制备方法本世纪初,各国生化学家将注意力集中在糖发酵的机制上。自Ｈａｒｄｅｎ和Ｙ...     

Fructose-1,6-diphosphate as an in vitro and in vivo anti-alcohol agent in the rat

Fructose-1, 6-diphosphate (FDP) decreases the effect of ethanol on Ca++ entry and inhibits the ethanol-stimulated phosphate efflux in rat heart slices. FDP also inhibits the ethanol-stimulated [36Cl-]-uptake by rat brain microvesicles and affects the isolated GABA-receptor in a way opposite to that of ethanol. The in vivo effects of FDP include a dose-dependent decrease in ethanol-induced gastric ulcers and a decrease in the serum transaminase levels raised by chronic ethanol administration. Other central actions of ethanol such as diuresis, narcosis, dependence and withdrawal symptoms are also counteracted by FDP.     

丙糖磷酸异构酶、果糖—1，6—二磷酸醛缩酶及果糖—1，6—二磷酸酶的共表达

致力于建立一条控制或降低大气中CO2浓度的途径,选择对 进行代谢工程以便改进其光合固定CO2的效率。作为研究的初始阶段,将编码丙糖磷酸异构酶、果糖－1,6－二磷酸醛缩酶及果糖－1,6－二磷酸酶的3个基因构建进一个由启动子trc控制的表达质粒pTrcFAT,成功地在大肠杆菌中实现了上述3个基因的活性共表达。活性测定结果显示：从1L培养液获得的破菌上清液每分钟可以催化二羟丙酮磷酸（DHAP）转化成700μmol果糖－6－磷酸。在此基础上进一步构建了这3个基因共表达的大肠杆菌－蓝藻穿梭表达质粒,也在大肠杆菌中实现了活性表达,当外泊基因的操纵子与载体质粒以大于1：1的比例进行构建时,可显著提高外源基因的表达量及相应的的酶活性。     

Fructose-1,6-diphosphate counteracts ethanol-stimulated calcium uptake in isolated BHK cells

Ethanol increases the uptake of ⁴⁵Ca by isolated baby hamster kidney (BHK) cells in vitro. The effect is dependent on ethanol and ⁴⁵Ca⁺⁺ concentration and on the incubation time. Fructose-1,6-diphosphate (FDP) added at different concentration during the pre-incubation exerts a protective effect through a membrane-stabilizing action which is consistent with its in vivo anti-alcohol activity documented in previous studies.     

Location of the Structural Gene for Fructose-1,6-Diphosphate Aldolase in Escherichia coli

Gene fda has been mapped, by co-transduction, between thyA and serA on the Escherichia coli chromosome.     

Properties of a Mutant of Escherichia coli with a Temperature-sensitive Fructose-1,6-Diphosphate Aldolase

B?ck, August (Purdue University, Lafayette, Ind.), and Frederick C. Neidhardt. Properties of a mutant of Escherichia coli with a temperature-sensitive fructose-1,6-diphosphate aldolase. J. Bacteriol. 92:470-476. 1966.-A mutant of Escherichia coli in which fructose-1,6-diphosphate aldolase functions at 30 C but not at 40 C was used to study the physiological effect of a specific block in the Embden-Meyerhof glycolytic pathway. Growth of the mutant at 40 C was found to be inhibited by the presence of glucose or certain related compounds in the medium. At 40 C, glucose was metabolized at 30 to 40% of the control rate and was abnormal in that glucose was converted into other six-carbon substances (probably gluconate, in large part) that were released into the culture medium. The inhibition was complete, but transient; its duration depended upon the initial amount of inhibitor added. The resumption of growth at 40 C was correlated with the further catabolism of the excreted compounds. When glycerol was used to grow the mutant at 40 C, the growth inhibition by glucose was accompanied by cessation of glycerol metabolism. Growth on alpha-glycerol phosphate was not inhibited under these conditions, implicating glycerol kinase as a possible site of inhibition; no inhibition of glycerol kinase by sugar phosphates, however, could be detected in vitro. The inhibitory effect of glucose on growth at 40 C is not caused by a deficit of intracellular adenosine triphosphate, but may be the result of a generalized poisoning of many cell processes by a greatly increased intracellular concentration of fructose-1,6-diphosphate, the substrate of the damaged enzyme.     

Ischemia and Reperfusion: Effect of Fructose-1,6-Bisphosphate

Several lines of evidence indicating a close relationship among ischemia, concentration of high-energy metabolites and onset of the “oxygen paradox” in reperfused tissues have been published. In this framework, we have recently studied the effects of exogenous fructose-1,6-bisphosphate on energy metabolism and on oxygen free radical damages of isolated rat heart subjected to anoxia and reoxygenation. In comparison with control groups, hearts perfused in the presence of 5mM fructose-1,6-bisphosphate throughout the different perfusion conditions showed higher concentrations of energy metabolites at the end of anoxia, most of which were normalized after reperfusion. Furthermore, in comparison with control hearts, a reduction of tissue malondialdehyde and of lactate dehydrogenase release in the perfusate was observed in fructose-1,6-bisphosphate-perfused hearts. In this article we review most of the available data concerning the ability of fructose-1,6-bisphosphate to protect from ischemia and reperfusion damage outlining those recent findings which contributed both to clarify the pharmacological profile of the drug and to give an insight in its probable mechanism of action.     

Structure and Activity of the Metal-independent Fructose-1,6-bisphosphatase YK23 from Saccharomyces cerevisiae

Fructose-1,6-bisphosphatase (FBPase), a key enzyme of gluconeogenesis and photosynthetic CO₂ fixation, catalyzes the hydrolysis of fructose 1,6-bisphosphate (FBP) to produce fructose 6-phosphate, an important precursor in various biosynthetic pathways. All known FBPases are metal-dependent enzymes, which are classified into five different classes based on their amino acid sequences. Eukaryotes are known to contain only the type-I FBPases, whereas all five types exist in various combinations in prokaryotes. Here we demonstrate that the uncharacterized protein YK23 from Saccharomyces cerevisiae efficiently hydrolyzes FBP in a metal-independent reaction. YK23 is a member of the histidine phosphatase (phosphoglyceromutase) superfamily with homologues found in all organisms. The crystal structure of the YK23 apo-form was solved at 1.75-Å resolution and revealed the core domain with the α/β/α-fold covered by two small cap domains. Two liganded structures of this protein show the presence of two phosphate molecules (an inhibitor) or FBP (a substrate) bound to the active site. FBP is bound in its linear, open conformation with the cleavable C1-phosphate positioned deep in the active site. Alanine replacement mutagenesis of YK23 identified six conserved residues absolutely required for activity and suggested that His¹³ and Glu⁹⁹ are the primary catalytic residues. Thus, YK23 represents the first family of metal-independent FBPases and a second FBPase family in eukaryotes.