色氨酸, 天然产物生物合成中的重要结构单元

氨基酸作为生物体内组成生命物质的小分子化合物, 在天然产物生物合成中扮演了非常重要的作用。色氨酸含有一个独特的吲哚环, 相对复杂的吲哚环平面结构使得色氨酸相比其他氨基酸具有更多的修饰空间。在微生物天然产物生物合成研究中, 色氨酸及其衍生物经常作为组成模块参与到天然产物的生物合成中, 本文概述了色氨酸几种不同的生物修饰方式, 包括烷基化修饰、卤化修饰、羟基化修饰、以及吲哚环的开环重排反应等。分析并总结色氨酸在天然产物生物合成中的作用可以增加我们对天然产物结构多样性的认识和推动天然产物生物合成机制的研究。     

聚乙二醇支载有机小分子合成的研究进展

本研究综述了聚乙二醇（PEG）支载的有机小分子合成研究的进展,从PEG所支我的直链化合物包括胺化产物、酰胺化合物、硫脲及取代硫脲化合物、其他化合物,从PEG所支载的杂环化合物包括单杂原子杂环、多杂原子杂环等两大方面分类讨论了所支载的有机小分子的合成方法,在此基础上对聚乙二醇作为载体的研究前景进行了展望。     

雷公藤二萜类化合物精细立体结构研究

雷公藤二萜内酯类化合物在结构上有一定的相似性:它们均含有3个六元环、1个五元内酯环和1～3个二元氧环,并且具有多种生物活性。本文选择了7个具有代表性的雷公藤二萜内酯化合物并通过X衍射分析获得其三维结构数据,以已有的药理实验数据为基础,对其精细立体结构变化和生物活性关系进行了探讨。研究结果表明:雷公藤萜内酯类化合物中的A、B、C三个六元环是其活性骨架的几何依托;18位上的羰基和7～8位上的三元氧环是其活性的可能结合部位;而该类化合物的活性部位则集中在C环的取代位置上;D环不是该类化合物具有生物活性的必需骨架部分。     

环氧角鲨烯合成通路在大肠杆菌中的构建和优化

三萜类化合物是一类广泛应用于医药、保健和化妆品等行业的天然产物,具有巨大的商业价值。生物合成三萜类化合物依赖于环氧角鲨烯的高效合成。角鲨烯环氧化酶是整个合成途径中的关键酶,其催化NADPH依赖的环氧化反应将角鲨烯转变为环氧角鲨烯。通过筛选不同来源的角鲨烯环氧化酶,截短的大鼠角鲨烯环氧化酶(RnSETC)在大肠杆菌Escherichia coli工程菌中表现出最强的活性;进一步考察内源性细胞色素P450还原酶样(CPRL)蛋白对环氧角鲨烯合成的影响显示,在中度拷贝质粒上以Lac启动子调控NADH:醌氧化还原酶(WrbA)的表达使得环氧角鲨烯产量提高近2.5倍。研究结果表明,所构建的环氧角鲨烯合成途径可以在大肠杆菌中实现三萜类合成关键前体环氧角鲨烯的合成,为生物合成三萜类化合物提供了重要借鉴。     

乙内酰脲类化合物的研究进展

乙内酰脲类化合物是一种五元杂环类化合物,具有多种的药理活性,且合成方法多样,由于首次从中药白附子中分离得到天然的乙内酰脲类化舍物,故对此类化合物作此综述,以便对乙内酰脲类化合物做进一步的研究。     

膦酸天然产物中碳磷键生物合成机制的研究进展

膦酸天然产物是指生物体产生的结构中含有碳磷键的小分子化合物,它因为与细胞中的羧酸和磷酸化的化合物结构相似,常作为某些生命活动必需的酶抑制剂,表现出良好的生物抑制活性。已知的膦酸天然产物碳磷键合成机制可以分为四类:磷酸烯醇式丙酮酸变位酶(PepM)催化类、磷甲基转移酶(PhpK)催化类、由S-2-羟基丙基膦酸环氧化酶(HppE)催化类和一种未知的碳磷键合成机制。本文就膦酸天然产物中碳磷键生物合成机制进行综述。     

二硫吡咯酮类抗生素的生物合成与代谢工程应用北大核心CSCD

二硫吡咯酮类抗生素是一类具有独特的吡咯酮二硫杂环戊二烯(4H-[1,2]二硫[4,3-b]吡咯-5-酮)骨架的化合物的总称。基于N-7位酰基侧链的不同以及N-4位是否含有甲基,可分为N-methyl-Nacylpyrrothine、N-acylpyrrothine和thiomarinols等类别。迄今为止,已有27种该类化合物被报道,重要代表包括全霉素(holomycin)、硫藤黄菌素(thiolutin)、金霉素(aureothricin)以及最近发现的thiomarinols。就生物活性而言,二硫吡咯酮类抗生素具有广谱的抗细菌活性,对多种微生物,包括革兰氏阴性菌、革兰氏阳性菌以及寄生虫都有较好的杀灭活性。甚至一些二硫吡咯酮衍生物表现出较强的抗肿瘤活性。近几年来,多个二硫吡咯酮类抗生素的生物合成基因簇相继被报道,其生物合成机理也逐步被阐明。本文将针对目前国内外二硫吡咯酮类抗生素的生物合成研究进展,以及在组合生物合成与代谢工程领域所取得的成果进行综述,旨在为通过合成生物学的方法创造结构新颖、高效低毒的"非天然"二硫吡咯酮类化合物提供理论借鉴。     

链霉菌Streptomyces antibioticus NRRL 8167中Naphthgeranine A生物合成基因簇的分析鉴定

【背景】微生物来源的天然产物是小分子药物或药物先导物的重要来源。对链霉菌Streptomyces antibioticus NRRL 8167的基因组分析显示,其包含多个次级代谢产物的生物合成基因簇,具有产生多种新化合物的潜力。【目的】对链霉菌S. antibioticus NRRL 8167中次级代谢产物进行研究,以期发现结构新颖或生物活性独特的化合物,并对相应产物的生物合成基因簇和生物合成途径进行解析。【方法】利用HPLC图谱结合特征性紫外吸收和LC-MS方法,排除S. antibioticus NRRL 8167产生的已知化合物,确定具有特殊紫外吸收的化合物作为挖掘对象,然后利用正、反相硅胶柱色谱、高效液相色谱等技术对次级代谢产物进行分离纯化,分离化合物。利用质谱及核磁共振光谱技术对化合物结构进行解析和鉴定;提取链霉菌S. antibioticus NRRL 8167基因组DNA,利用PacBio测序平台进行基因组测序;利用生物信息学对基因组进行注释,并对合成该化合物的基因簇进行定位分析,推导其生物合成途径。【结果】确定这个化合物是NaphthgeranineA,属于聚酮类化合物。全基因组序列分析发现S.antibioticusNRRL8167基因组含有28个次级代谢产物生物合成基因簇,其中基因簇20可能负责Naphthgeranine A的生物合成,并对其生物合成途径进行了推导。【结论】基于紫外吸收光谱和质谱特征,从S. antibioticus NRRL 8167菌株的发酵提取物中分离鉴定了一个聚酮类化合物Naphthgeranine A。该菌株的全基因组测序为其生物合成基因簇的鉴定提供了前提,对Naphthgeranine A生物合成基因簇和生物合成途径的推测为进一步研究这个化合物的生物合成机制奠定了基础。     

Combretastatin A-4顺式锁定衍生化研究进展

Combretastatin A-4(CA4)是天然抗肿瘤化合物,其顺式二苯乙烯构型对活性起关键作用。采用环状结构进行CA4的顺式构型锁定已成为目前结构改造的主要思路。本文从三元环、五元环、六元环锁定及骨架延伸锁定等方面综述了近年来CA4烯碳桥顺式锁定改造及衍生化的研究进展。     

代谢工程在芳香化合物生物合成研究中的应用

生物技术和代谢工程的发展促进了生物合成研究。概述了近年来利用微生物莽草酸途径进行芳香化合物生物合成研究的现况、代谢工程在提高天然芳香化合物产量和扩大合成非天然产生的芳香化合物范围的应用的进展 ,特别是整体代谢工程对提高第二代工程菌产量的作用。指出了生物合成法是生产氨基酸及其它生物小分子如奎尼酸、维生素和抗生素等的未来趋势 ,在工业化生产中有着广阔的应用前景。     

Ring cleavage of sulfur heterocycles: how does it happen?

Sulfur heterocycles are common constituents of petroleum and liquids derived from coal, and they are found in some secondary metabolites of microorganisms and plants. They exist primarily as saturated rings and thiophenes. There are two major objectives driving investigations of the microbial metabolism of organosulfur compounds. One is the quest to develop a process for biodesulfurization of fossil fuels, and the other is to understand the fates of organosulfur compounds in petroleum- or creosote-contaminated environments which is important in assessing bioremediation processes. For these processes to be successful, cleavage of different types of sulfur heterocyclic rings is paramount. This paper reviews the evidence for microbial ring cleavage of a variety of organosulfur compounds and discusses the few well-studied cases which have shown that the C-S bond is most susceptible to breakage leading to disruption of the ring. In most cases, the introduction of one or more oxygen atom(s) onto the adjacent C atom and/or onto the S atom weakens the C-S bond, facilitating its cleavage. Although much is known about the thiophene ring cleavage in dibenzothiophene, there is still a great deal to be learned about the cleavage of other sulfur heterocycles.     

Bacterial metabolism of fluorene, dibenzofuran, dibenzothiophene, and carbazole

Fluorene and its three heteroatomic analogs, dibenzofuran, dibenzothiophene, and carbazole, are environmental contaminants in areas impacted by spills of creosote. In addition, dibenzofuran has been used as an insecticide, and it is formed from the photolysis of chlorinated biphenyl ethers. Many biodegradation studies of dibenzofuran have considered it as a model for chlorinated dibenzofurans, which are of greater environmental concern. This paper reviews the bacterial degradation of fluorene and its analogs. These compounds are susceptible to three different modes of initial oxidation: (i) the naphthalene-like attack, in which one of the aromatic rings is oxidized to a dihydrodiol; (ii) an angular dioxygenase attack, in which the carbon bonded to the methylene group in fluorene or to the heteroatoms in the analogs, and the adjacent carbon in the aromatic ring are both oxidized; and (iii) the five-membered ring attack, in which the methylene carbon atom in fluorene or the sulfur atom in dibenzothiophene is oxidized. The metabolites, enzymology, and genetics of these transformation are summarized. Literature data are presented, indicating that the electronegativity of the atom connecting the two aromatic rings influences the attack of the angular dioxygenase. In dibenzofuran and carbazole, the connecting atoms, O and N respectively, have high electronegativities, and these compounds serve as substrates for angular dioxygenases. In contrast, the connecting atoms in dibenzothiophene and fluorene, S and C respectively, have lower electronegativities, and these atoms must be oxidized before the angular dioxygenases attack these compounds.     

1,2,3-Triazole-containing hybrids as leads in medicinal chemistry: A recent overview

The 1,2,3-triazole ring is a major pharmacophore system among nitrogen-containing heterocycles. These five-membered heterocyclic motifs with three nitrogen heteroatoms can be prepared easily using ‘click’ chemistry with copper- or ruthenium-catalysed azide-alkyne cycloaddition reactions. Recently, the ‘linker’ property of 1,2,3-triazoles was demonstrated, and a novel class of 1,2,3-triazole-containing hybrids and conjugates was synthesised and evaluated as lead compounds for diverse biological targets. These lead compounds have been demonstrated as anticancer, antimicrobial, anti-tubercular, antiviral, antidiabetic, antimalarial, anti-leishmanial, and neuroprotective agents. The present review summarises advances in lead compounds of 1,2,3-triazole-containing hybrids, conjugates, and their related heterocycles in medicinal chemistry published in 2018. This review will be useful to scientists in research fields of organic synthesis, medicinal chemistry, phytochemistry, and pharmacology.     

Theoretical studies on penicillins,penicillin sulphones and their 1-oxa-1-dethia and 1-carba-1-dethia analogues: binding specificities of transeptidases and penicillinases

Empirical potential energy calculations have been carried out to determine the preferred conformations of penicillins and penicillin sulphones and their 1-oxa-1-dethia and 1-carba-1-dethia analogues. With the exception of 1-oxa-1-dethia penicillins, all the other compounds favour C₂ and the C₃ puckered conformations of their five-membered rings. Replacement of C2 methyl groups by hydrogen atoms as in bisnorpenicillin V or oxidation of sulphur in position 1 as in sulphones, makes the C₃ puckered form much less favourable. Addition of an amino-acyl group at the C6 atom, however, makes the C₃ puckered form more favoured in penicillin G or V and in 1-carba-1-dethia penicillins. Through the replacement of the sulphur atom at position 1 by an oxygen atom or by a -CH₂ group increases the non-planarity of the lactam peptide bond, it significantly affects the relative disposition of the C3 carboxyl group with respect to the β-lactam ring. These conformational differences have been correlated with the biological activities of these compounds. The present study suggests that the conformation of the bicyclic ring system may be more important for initial binding with the crosslinking enzyme(s) involved in the biosynthesis of bacterial cell-wall peptidoglycan and that the mode of binding is influenced by the nature of the side-group at the C6 atom. These studies predict, in agreement with experimental results, that the 1-oxa-1-dethia penicillin nulceus is an inhibitor of penicillianses. The study also suggests that the stereospecificities of the crosslinking enzyme(s) and penicillinases are very similar with regard to the nature of the side-group at the 6 atom and the confirmation of the bicyclic ring system. However, the confirmational requirement for the bicyclic ring system appears to be more specific in the former enzyme than in the latter.     

Structural requirements of some sulphonamides that possess an antifertility activity in male rats

Sulphonamides with different chemical structures were synthesized and these 13 compounds together with 7 commercially available sulpha drugs were tested for antifertility activity by natural mating in male rats. All compounds were given daily by gastric intubation at doses of 125, 150, 250 or 450 mg/kg for 6 weeks. Sulphapyridine caused a dose-related and reversible reduction in fertility at doses between 125 and 450 mg/kg. At the high dose, fertility was reduced to 25.9% of control at 5 weeks after treatment, and complete recovery occurred by 3 weeks after drug withdrawal. This activity was abolished when the pyridine ring was substituted by other heterocyclic rings, except sulphachloropyridazine which had only weak activity. Replacement of the pyridine ring by a hydrogen atom or short aliphatic chains preserved or even enhanced the potency. Thus, sulphanilamide, N1-methylsulphanilamide or N1-diethylsulphanilamide produced a marked but reversible reduction in fertility. Removal or substitution of the N4-amino group on the benzene ring of sulphapyridine with a methyl group destroyed the activity. However, the bromo or nitro analogue (at the para- but not the meta-position of the benzene ring) still possessed some activity. N4-Acetyl derivatives of sulphapyridine, sulphanilamide, and N1-diethylsulphanilamide were as potent as their parent compounds. These results suggest that the presence of pyridine or other heterocyclic rings is not necessary for the antifertility activity of sulphonamide compounds. However, the N4-amino group is indispensable. In addition, acetylation of this amino group does not change the potency. The prototype of the antifertility sulphonamides therefore seems to be sulphanilamide.     

Isoxazole-type derivatives related to combretastatin A-4, synthesis and biological evaluation

Novel combretastatin analogues bearing various five-membered heterocycles with consecutive oxygen and nitrogen atoms, in place of the olefinic bridge of CA4, have been synthesized (isoxazole, isoxazoline, oxadiazole, etc). These compounds have been evaluated for cytotoxicity and their ability to inhibit the tubulin assembly. On the basis of the relative position of the aromatic A- and B-rings on the heterocyclic moiety, they could be split in two classes, the alpha,gamma- or alpha,beta-diaryl heterocyclic derivatives. In the first series, the 3,5-diaryloxadiazole 9a displayed comparable antitubulin activity to that of CA4, but was devoid of cytotoxic effects. Among the alpha,beta-diaryl heterocyclic derivatives, the 4,5-diarylisoxazole 35 exhibited greater antitubulin activity than that of CA4 (0.75 vs 1.2 microM), but modest antiproliferative activity. These data showed that minor alteration in the chemical structure of the heterocyclic ring and its relative orientation with regard to the two phenyl rings of CA4 could dramatically influence the tubulin binding properties.     

Biosynthesis of Indolocarbazole and Goadsporin,Two Different Heterocyclic Antibiotics Produced by Actinomycetes

The biosynthesis of staurosporine, rebeccamycin, and goadsporin, which are produced by actinomycetes and contain characteristic heterocyclic rings, was characterized by genetic methods. Staurosporine and rebeccamycin contain an indolocarbazole ring synthesized from two molecules of tryptophan, with indolepyruvic acid imine and chromopyrrolic acid as biosynthetic intermediates. A tetrameric hemoprotein synthesizes chromopyrrolic acid, and cytochrome P450 peroxidase catalyzes the intramolecular C–C coupling and decarboxylation of chromopyrrolic acid to form the indolocarbazole core. Goadsporin is a thiopeptide containing thiazole and oxazole heterocyclic rings. The structural gene godA is ribosomally translated to a goadsporin precursor peptide, and oxazole, methyloxazole, and thiazole rings are derived from serine, threonine, and cystein through post-translational modifications. On the basis of these knowledges, a wide variety of indolocarbazole and goadsporin analogs through the rational gene recombination and disruption of these biosynthetic genes were successfully produced.     

Naturally occurring thiophenes: isolation,purification, structural elucidation,and evaluation of bioactivities

Phytochemistry Reviews - Thiophenes are a class of heterocyclic aromatic compounds based on a five-membered ring made up of one sulfur and four carbon atoms. The thiophene nucleus is well...     

Inhibition of prolyl oligopeptidase with a synthetic unnatural dipeptide

A new inhibitor, containing a linked proline-piperidine structure, for the enzyme prolyl oligopeptidase (POP) has been synthesised and demonstrated to bind covalently with the enzyme at the active site. This provides evidence that covalent inhibitors of POP do not have to be limited to structures containing five-membered N-containing heterocyclic rings.     

Design and synthesis of novel HDAC8 inhibitory 2,5-disubstituted-1,3,4-oxadiazoles containing glycine and alanine hybrids with anti cancer activity

Oxadiazole is a heterocyclic compound containing an oxygen atom and two nitrogen atoms in a five-membered ring. Of the four oxadiazoles known, 1,3,4-oxadiazole has become an important structural motif for the development of new drugs and the compounds containing 1,3,4-oxadiazole cores have a broad spectrum of biological activity. Herein, we describe the design, synthesis and biological evaluation of a series of novel 2,5-disubstituted 1,3,4-oxadiazoles (10a–10j) as class I histone deacetylase (HDAC) inhibitors. The compounds were designed and evaluated for HDAC8 selectivity using in silico docking software (Glide) and the top 10 compounds with high dock score and obeying Lipinski’s rule were synthesized organically. Further the biological HDAC inhibitory and selectivity assays and anti-proliferative assays were carried out. In in silico and in vitro studies, all compounds (10a–10j) showed significant HDAC inhibition and exhibited HDAC8 selectivity. Among all tested compounds, 10b showed substantial HDAC8 inhibitory activity and better anticancer activity which is comparable to the positive control, a FDA approved drug, vorinostat (SAHA). Structural activity relation is discussed with various substitutions in the benzene ring connected on 1,3,4-oxadizole and glycine/alanine. The study warranted further investigations to develop HDAC8-selective inhibitory molecule as a drug for neoplastic diseases. Novel 1,3,4-oxadizole substituted with glycine/alanine showed HDAC8 inhibition.