Fine synthetic nucleoside chemistry based on nucleoside natural products synthesis

Synthetic nucleoside chemistry based on nucleoside natural products synthesis were described. First, a samarium diiodide (SmI 2)-promoted aldol reaction with the use of alpha-phenylthioketone as an enolate was developed. The characteristics of this reaction are that the enolate can be regioselectively generated and the aldol reaction proceeds under near neutral condition. This reaction is proved to be a powerful reaction for the synthesis of complex nucleoside natural products, and herbicidin B and fully protected tunicaminyluracil, which were undecose nucleoside natural products, were synthesized. Next, the synthetic methodology of the caprazamycins, which are promising antibacterial nucleoside natural products, was also developed by the strategy including beta-selective ribosylation without using a neighboring group participation. Our synthetic route provided a range of key analogues with partial structures to define the pharmacophore. Simplification of the caprazamycins was further pursued to develop diketopiperazine analogs.     

Photochemical reaction detection of phylloquinone and menaquinones. A comparison with chemical post-columns reduction for fluorescence detection

Summary A new photochemical reaction method for the on-line fluorimetric detection of natural vitamin K homologs was developed. In addition to its high sensitivity, the method features an interesting selectivity for the determination of these compounds in a complex matrix such as human serum. The formation of different photolysis products as a function of reaction conditions, and the optimalisation of a segmented flow reaction system will be discussed. The results indicate that the method is 4 times more sensitive than UV detection, and at least as selective as fluorescence detection after post-column chemical reduction.     

Recent advances of intermolecular Diels–Alder reaction in bio-inspired synthesis of natural products

The Diels–Alder(D–A)reaction is one of the most powerful reactions in organic synthesis.The intermolecular D–A reaction attracts much less attentions than its intramolecular counterpart in natural product synthesis,possibly due to the issues of reactivity and selectivity.In the past decade,the intermolecular D–A reaction has been increasingly utilized in the total synthesis of structurally complex natural products.In this article,we present a few examples for the elegant applications of the intermolecular D–A reaction that are inspired by biosynthetic hypotheses of the target natural products.These examples demonstrate that D–A reaction is not only useful for preparing building blocks but also powerful for coupling structurally complicated and sterically demanding segments in a highly chemo-and stereo-controlled fashion,which may inspire further developments of intermolecular D–A reaction from both strategy and methodology perspectives.     

Synthesis of the Bicyclic Lactone Core of Leonuketal,Enabled by a Telescoped Diels–Alder Reaction Sequence

The Diels–Alder cycloaddition reaction has become established as a fundamental approach for the preparation of complex natural products; however, successful application of the intermolecular Diels–Alder cycloaddition reaction to the synthesis of particularly congested scaffolds remains surprisingly problematic. Inspired by the terpenoid spiroketal natural product leonuketal, a challenging telescoped reaction sequence has been realized to access the core [2.2.2]‐bicyclic lactone ring system and its [3.2.1] isomer. Our four‐step, protecting‐group‐free process required detailed investigation to circumvent the problems of adduct fragmentation and intermediate instability. Successful solution of these practical issues, along with unambiguous structural determination of the target structures, provide useful insights that will facilitate future applications of the Diels–Alder cycloaddition reaction to challenging, highly congested molecular scaffolds and ongoing synthetic efforts towards this natural product.     

Schmidt反应及其在全合成中的应用

主要介绍了Schmidt反应的机理,影响Schmidt重排的因素,以及Schmidt反应在天然产物和具有生物活性的复杂含氮化合物合成中的应用。     

Chemistry and biology of biosynthetic Diels-Alder reactions

Nature's repertoire of biosynthetic transformations has recently been recognized to include the Diels-Alder cycloaddition reaction. Evidence now exists that there are enzymes that mediate the Diels-Alder reaction in secondary metabolic biosynthetic pathways. 2002 marked the 100th anniversary of Alder's birth and 75 years since the discovery of the Diels-Alder reaction. It would appear that living systems discovered and made use of this ubiquitously useful ring-forming reaction eons ago for the construction of complex natural products. In this Review an overview is given of all of the known classes of natural products (polyketides, isoprenoids, phenylpropanoids, alkaloids) that have been speculated to arise by a biological Diels-Alder reaction.     

Dinitrogen extrusion from diazene in organic synthesis

Radical-mediated reactions have many advantages in the construction of complex molecular scaffolds by forging chemical bonds of high challenge. Diazenes, including 1,1-diazenes and 1,2-diazenes, can generate biradical species via nitrogen extrusion under thermal or photochemical conditions. The superior reactivity of the generated biradical enables various types of synthetic transformations with excellent chemoselectivity and has been applied to the complex natural products synthesis. In this mini-review, the modes of reaction are summarized and discussed, namely ring contraction via nitrogen deletion, homo or hetero-dimerization, trimethylenemethane (TMM)-diyl cycloaddition. Applications of these classes of reactions in complex natural product synthesis are illustrated. Last but not least, the current state, future directions, and opportunities for dinitrogen extrusion reaction from diazenes are highlighted and discussed.     

Model studies towards paecilomycine A-C: exploring scaffold diversity through a key intramolecular Pauson-Khand reaction

A diversity generative approach to bioactive and structurally complex natural products paecilomycine A-C, involving an intramolecular Pauson-Khand reaction as a key step is delineated.     

Two Versatile and Parallel Approaches to Highly Symmetrical Open and Closed Natural Product‐Based Structures

Two parallel approaches for preparing diverse and highly symmetrical homohybrids derived from a series of mono‐ and diterpenes, steroids, and alkaloids are reported. Both procedures are based on the mono‐addition of bis(alkynyl) dilithium reagents to natural products having a carbonyl group to produce the corresponding alkynyl derivatives. The Glaser–Hay Cu‐promoted homocoupling of these alkynyl natural product mono‐adducts as well as the Huisgen Cu‐catalyzed azide–alkyne cycloaddition (CuAAC) reaction resulted in the synthesis of steroid‐, terpene‐, and alkaloid‐based homohybrid derivatives incorporating diverse spacers to join the natural product scaffolds. Straightforward entries to novel closed highly symmetrical and complex estrone‐based macrocyclic and cage architectures by means of the Glaser–Eglinton homocoupling and the CuAAC reaction have been devised.     

The Preparation and Evaluation of Electron Poor Benzylidene Fischer Carbene Complexes: Studies Toward the Total Synthesis of (+)-Olivin

The continued exploration into the fate of the benzannulation reaction is put forth using the electronic nature of substituents on the aryl ring of benzylidene Fischer carbene complexes as a handle to predict, using σ-para values as a guide, the outcome of the reaction based on the accepted mechanism. The design of this work focuses on evaluation of the synthetic utility of the benzannulation reaction and the means by which this reaction may be improved to be a better synthetic tool in the preparation of complex natural products as this is illustrated in our ongoing total synthesis of (+)-olivin which uses the benzannulation reaction as the key convergent synthetic step. To accomplish these tasks, the preparation of several electron poor benzylidene Fischer carbene complexes was carried out and their reaction with simple alkyne substrates studied. While much is known about the preparation of electron rich benzylidene Fischer carbene complexes, little is known about the preparation of their electron poor counterparts. Thus efforts toward developing useful preparative methods of these elusive targets has also been studied. While the use of both carbon and oxygen based aryl substituents has been explored, to date the preparation of benzylidene carbene complexes containing oxygen based aryl substituents has been exploited to a greater degree since these systems carry more immediate synthetic importance. This is so because the skeletal core of many of the natural products that have been targeted with the benzannulation reaction including (+)-olivin contain a highly oxygenated polycyclic aromatic core. The enhancement in efficiency of the benzannulation reaction using this synthetic methodology is demonstrated by the successful completion of the convergent synthetic step in the total synthesis of (+)-olivin.     

Biomimetic synthesis of pyrone-derived natural products: exploring chemical pathways from a unique polyketide precursor

Our biomimetic hypothesis proposes that families of diverse natural products with complex core structures such as 9,10-deoxytridachione, photodeoxytridachione and ocellapyrone A are derived in nature from a linear and conformationally strained all-( E) tetraene-pyrone precursor. We therefore synthesized such a precursor and investigated its biomimetic transformation under a variety of reaction conditions, both to the above natural products as well as to diverse isomers which we propose to be natural products "yet to be discovered". We also report herein the first synthesis of the natural product iso-9,10-deoxytridachione.     

不同催化体系下腈的水合反应研究进展

腈可用于构建新的碳-碳、碳-杂原子键,所得产物丰富多样.酰胺基团广泛存在于医药、农药和天然产物中,此外,酰胺还是有机合成反应中重要的中间体.在目前报道的酰胺类化合物的合成方法中,腈的水合反应已成为学术界和工业界最广泛使用的获得初级酰胺类化合物的方法之一.早期腈的水合反应中通常涉及强酸、强碱的使用,但在该类反应体系下,往...     

Cobalt- versus ruthenium-catalyzed Alder-ene reaction for the synthesis of credneramide A and B

The first synthesis of the natural products credneramide A and B was accomplished by utilizing Alder-ene reactions between a terminal alkene and an internal alkyne to generate the rather uncommon 1,4-diene substructure of these compounds. Moreover, two different short linear sequences toward these targets are evaluated using either a cobalt-catalyzed Alder-ene reaction of 1-chloropent-1-yne or a ruthenium-catalyzed Alder-ene reaction of 1-trimethylsilyl-1-pentyne with 5-hexenoic acid derivatives in the key step transformation. In addition, saponification of the primary Alder-ene product derived from the cobalt-catalyzed Alder-ene reaction led to credneric acid, the biological precursor of both natural products.     

Iron-catalyzed ene-type propargylation of diarylethylenes with propargyl alcohols

The diarylalkenyl propargylic complex framework has been found in many natural products and medicinal regents. Herein, we have disclosed an unprecedented FeCl(3) catalyzed ene-type reaction of propargylic alcohols with 1,1-diaryl alkenes which enabled us to furnish a diarylalkenyl propargylic complex framework in moderate to high chemical yields (up to 98%).     

α,β-不饱和内酯的光化学反应研究进展

α,β-不饱和内酯的光化学反应可广泛应用于核苷、稠环生物碱、萜类、甾类等多种光学活性物质与天然产物的合成中.根据不同的反应类型,综述了2(5H)-呋喃酮等α,β-不饱和内酯的光化学1,4-加成反应、1,4-加成-并环反应、[2+2]环加成反应和复杂环加成反应的新进展.     

One-step transformation of tricyclopentabenzene (trindane, C(15)H(18)) to bicyclo(10.3.0)pentadec-1(12)ene- 2,6,7,11-tetrone (C(15)H(18)O(4)) and its aldol product, 12-hydroxy-16-oxatetracyclo(10.3.1.0.(1,5)0(7,11))hexadec-7(11)ene-2,6-dione (C(15)H(18)O(4))

[reaction: see text] Ozonolysis of 1 largely results in 2 and 3, having features similar to several classes of natural products. The retention of the C(15) pericycle suggests preference for the cleavage of pi-bonds endo to the cyclopentane ring. This unique property of trindane offers opportunities for synthesis of complex natural products from this hydrocarbon that can be made in quantity by acid-catalyzed trimerization of cyclopentanone.     

Total synthesis and biosynthesis of the paraherquamides: an intriguing story of the biological Diels-Alder construction

The syntheses and biosyntheses of the paraherquamide and brevianamide families of prenylated indole-derived alkaloids are reviewed. It has been proposed that the unique bicyclo[2.2.2]diazaoctan ring system that is common to this family of natural products, arises by a biological intramolecular Diels-Alder cycloaddition reaction. Both synthetic approaches and total syntheses of several members of this family of natural products are reviewed. The biosynthesis of these alkaloids has also constituted an active area of research and the current state of knowledge on the biosynthesis of these natural products are reviewed.     

Synthesis of the western half of the lolicines and lolitrems

[reaction: see text] The synthesis of the highly substituted indole portion of the complex tremorgenic natural products lolicine A and B is presented. The Diels-Alder reaction of a quinone monoimine enables the synthesis of an appropriately substituted indole. The key step in the synthesis is a tandem isopropenyl cuprate addition/aldol cyclocondensation which provides the necessary functionality for elaboration to the 2,2,5,5-tetramethyltetrahydrofuran.     

Total synthesis and absolute configuration of otteliones A and B, novel and potent antitumor agents from a freshwater plant

[reaction: see text] The first enantioselective total synthesis of otteliones A and B, biologically important and structurally novel natural products, has been successfully achieved. This total synthesis fully confirms the absolute configuration of these natural products.     

Access to polyfunctionalized diquinanes, hydrindanes, and decalines via TiCl4 promoted Michael-aldol and Baylis-Hillman reactions

The addition of 0.5 equiv of TiCl(4) to (cyclo)alkanones tethered to α,β-unsaturated ketones afforded polyfunctionalized diquinanes, hydrindanes, and decalines. These products, resulting from a Michael-aldol or a Baylis-Hillman reaction, can be obtained with high or total diastereoselectivity in moderate to high yields. These scaffolds represent interesting building blocks for the synthesis of complex natural products.