Alkyne derivatives natural products synthesis

Sufficient information about the reaction has been gathered to allow fairly accurate predictions of yield as well as of stereo- and regioselectivity.176177 The reaction proceeds via the formation of hexacarbonylalkyne-dicobalt complexes and is remarkably tolerant of functional groups in both the alkyne and the alkene. The intramolecular Pauson-Khand reaction is an effective way of preparing bi- and polycyclic systems, and the cyclization of 1,6-heptenyne derivatives to give bicyclo[3.3.0]oct-l-en-3-ones has been the most popular application of the Pauson-Khand reaction in natural product synthesis [Eq. (17)]. 

Alkynic ketones have been used extensively in natural product synthesis, due in large part to the contributions of Midland and coworkers and the development of generd methods for enantioselective reduction of this moiety to afford optically active propargyl alcohols using chiral trialkylboranes. Furthermore, the derived alkynic alcohol is a versatile system which can be manipulated directly into cis-or rra 5-allylic alcohols and as a precursor for vinylorganometallic species. This section will briefly cover progress made in the direct acylation of alkynic organolithiums with the acylation protocol d veloped by Weinreb (see also Section 1.13.2.7). 

The first step is dissociation of L(Ph3P), as addition of more triphenylphos-phine inhibits the catalysis. Other cyclopentadienylcobalt complexes CpCoL are also effective catalysts, (with = 1, 5-cyclooctadiene, 2C H or, less efficiently, 2CO). By replacing RC=CR with a nitrile RCN in the final step (i.e. by using a mixture of nitrile and alkyne), pyridines can be synthesized catalytically, although some benzene derivative is always obtained as well. These processes have been developed industrially for making pyridines and in the laboratory for effecting cycloadditions in natural product synthesis ... 

Other examples of [2C+2S+1C0] cycloaddition reactions have been described by Herndon et al. by the use of chromium cyclopropyl(methoxy)carbenes. These complexes react with alkynes releasing ethene and forming cyclopenta-dienone derivatives, which evolve to cyclopentenone derivatives in the presence of chromium(O) and water [122] (Scheme 76). This reaction has been extended to intramolecular processes and also to the synthesis of some natural products [123]. These authors have also described another process involving a formal [2C+2S+1C0] cycloaddition reaction. Thus, the reaction of methyl and cyclo-propylcarbene complexes with phenylacetylene derivatives does not afford the expected benzannulated products, and several regioisomers of cyclopentenone derivatives are the only products isolated [124] (Scheme 76). 

Snieckus and his group members [104] used the known domino Sonogashira/ Castro-Stephens reaction [105, 106] for the synthesis of the natural product pli-cadin (6/1-209), this having been isolated from Psorelia plicata in 1991 [107]. In this synthesis, Pd°-catalyzed reaction of the alkyne 6/1-210 and the iodobenzene derivative 6/1-211 in the presence of Cul led to the furan 6/1-212, which was transformed into 6/1-209 via 6/1-213 (Scheme 6/1.54). There are some discrepancies of the physical data of the natural and the synthetic product thus, it might be possible that the natural product has a different structure. It should also be mentioned that the... 

A solvent-free synthesis of benzo[b]furan derivatives 10-79, a class of compounds which is often found in physiologically active natural products, was described by Shanthan Rao and coworkers. These authors heated phosphorane 10-71 for 8 min in a microwave oven and obtained the benzo[b]furan 10-74 in 73% yield (Scheme 10.18) [25]. The sequence is initiated by an intramolecular Wittig reaction, providing alkyne 10-72 this underwent a subsequent Claisen rearrangement to give the intermediate 10-73. Also in this case, normal oil-bath heating gave much lower yields (5%) of the desired product the authors hypothesize that the micro-... 

The key feature of the first total synthesis of (+)-homopumiliotoxin 223G 418 was a Lewis acid-induced, chelation-controlled propargylation of the trifluoroacetate salt of (. )-2-acetyl pi peri dine 415, derived from iV-Cbz-L-pipecolinic acid. Alkyne 416 thus formed was transformed after several steps into 417, which was cyclized by activation of the primary hydroxyl with the carbon tetrabromide-triphenylphosphine system to give the natural product (Scheme 98) <1998TL2149>. 

Other examples of the iodonium ylide-based syntheses of furan derivatives involve cycloaddition reactions with alkenes or alkynes. Although the majority of these syntheses involve stable iodonium ylides (86JOC3453 94T11541) (e.g., Eqs. 16 and 17), in some cases the ylides are unstable and are generated in situ (92JOC2135) (e.g., Eq. 18). In the case of alkenes, dihydrofuran derivatives are obtained (Eqs. 16-18). This synthetic route is especially useful for the synthesis of dihydrobenzofuran derivatives that are related to the neolignan family of natural products (Eq. 18). 

The metal derivatives of alkynes can be added to carbonyl electrophiles as in the following examples. The first (we have reminded you of the mechanism for this) is the initial step of an important synthesis of the antibiotic, erythronolide A, and the second is the penultimate step of a synthesis of the widespread natural product, farnesol. 

Schreiber s early efforts in this area were focused on libraries of compounds having structural features reminiscent of rigid, complex, stereochemically rich natural products. In a key early example, solid-phase split-pool synthesis was used to generate a combinatorial library of over two million complex, polycyclic compounds derived from shikimic acid [17]. A stereoselective tandem acylation-nitrone cycloaddition was used to generate 18 tetracyclic scaffolds, to which 30 alkynes were coupled using a Sonogashira reaction, 62 amines were coupled via y -lactone aminolysis, and 62 carboxylic acids were coupled by alcohol esterification (Fig. 9.1-3(c)). In addition, a portion of the solid supports were left unreacted at each of the last three steps to generate a skip codon that further increased the diversity of the library. 

The last decade has witnessed the application of 1-halogenoacetylenes as crucial intermediates for the synthesis of increasingly complex structures, especially in natural product chemistry. In pheromone synthesis it is essential to create double-bond systems diastereoselec-tively, and a route often taken consists in the preparation of a suitable alkyne precursor which is then converted into the final olefin by various addition reactions (catalytic hydrogenation, metalation, etc.). For the construction of the alkyne precursor to the pheromone, 1-bromo-(94) and 1-iodoalkynes (95) have been particularly valuable since they can easily be subjected to metal-catalyzed coupling reactions [105]. For ocample, the unsaturated ester 163, which is a sex attractant of Lepidoptera (moths and butterflies), has been prepared by first converting the terminal acetylene 160 into its 1-iodo derivative 161. This is subsequently hydrogenated... 

Niphatesines A-H (4-11). Niphatesines A-D (4-7) showed antineoplastic activity and they were found in another Niphates species from the sea around Okinawa [123]. The total synthesis of 4-7 has been approached by two different research groups. A first regio/enantioselective synthesis was achieved (see Scheme 1) by making use of the extremely versatile Pd(0) chemistry, which assisted the 3-pyridine alkylation in the key step. At the same time the absolute configuration of niphatesin C (6) and D (7) was established [24]. A different, thiophene-based approach was used to complete the total synthesis of both enantiomers of niphatesin C (see Scheme 2). In this case the absolute configuration was established on the basis of the comparison of the sense of optical rotation with that of the natural product [25]. Niphatesin A (4) was also synthesized in a simple manner via an alkyne derivative (see Scheme 6). 

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