Enynes functionalized

The cross-coupling of alkynylzinc halides or fluorinated alkenylzinc halides with fluori-nated alkenyl iodides allows the preparation of a range of fluorinated dienes or enynes - Functionalized allylic boronic esters can be prepared by the cross-coupling of (dialkylbo-ryl)methylzinc iodide 428 with functionalized alkenyl iodides. The intramolecular reaction provides cyclized products, such as 429 (Scheme 109) ° °. In some cases, reduction reactions or halogen-zinc exchange reactions are observed. 

Depending on the substituents of l,6-enynes, their cyclization leads to 1.2-dialkylidene derivatives (or a 1.3-diene system). For example, cyclization of the 1,6-enyne 50 affords the 1.3-diene system 51[33-35]. Furthermore, the 1.6-enyne 53, which has a terminal alkene, undergoes cyclization with a shift of vinylic hydrogen to generate the 1,3-diene system 54. The carbapenem skeleton 56 has been synthesized based on the cyclization of the functionalized 1,6-enyne 55[36], Similarly, the cyclization of the 1,7-enyne 57 gives a si -mem-bered ring 58 with the 1,3-diene system. 

In general, hydroboration—protonolysis is a stereoselective noncatalytic method of cis-hydrogenation providing access to alkanes, alkenes, dienes, and enynes from olefinic and acetylenic precursors (108,212). Procedures for the protonolysis of alkenylboranes containing acid-sensitive functional groups under neutral or basic conditions have been developed (213,214). 

Scheme 27).43b A regiospecific monohydroboration of enyne 107 with disiamylborane furnishes (A)-vinylborane 108, a substance that combines stereospecifically with vinyl iodide 109 under the indicated conditions to give conjugated triene 110 (52% overall yield). Trisporol B benzyl ether (111) is obtained after acid-induced hydrolysis of the dioxolane ketal functions.

The lithium etiolate of acetaldehyde DMH has recently been utilized in the opening reaction of the ot-epoxide obtained by DM DO oxidation ofenol ether 142, to provide hemiacetal 143 after mild oxidative acid hydrolysis. The protected carbonyl functionality was subsequently used for the introduction of the trans enyne chain through a Wittig olefmation reaction to provide alcohol 144, which was then transformed into (+)-laurenyne (Scheme 8.37) [71]. 

The fact that pentacarbonyl carbene complexes react with enynes in a chemo-selective and regiospecific way at the alkyne functionality was successfully applied in the total synthesis of vitamins of the Kj and K2 series [58]. Oxidation of the intermediate tricarbonyl(dihydrovitamin K) chromium complexes with silver oxide afforded the desired naphthoquinone-based vitamin K compounds 65. Compared to customary strategies, the benzannulation reaction proved to be superior as it avoids conditions favouring (E)/(Z)-isomerisation within the allylic side chain. The basic representative vitamin K3 (menadione) 66 was synthesised in a straightforward manner from pentacarbonyl carbene complex 1 and propyne (Scheme 38). 

Hexacarbonyldicobalt complexes of alkynes have served as substrates in a variety of olefin metathesis reactions. There are several reasons for complex-ing an alkyne functionality prior to the metathesis step [ 125] (a) the alkyne may chelate the ruthenium center, leading to inhibition of the catalytically active species [125d] (b) the alkyne may participate in the metathesis reaction, giving undesired enyne metathesis products [125f] (c) the linear structure of the alkyne may prevent cyclization reactions due to steric reasons [125a-d] and (d) the hexacarbonylcobalt moiety can be used for further transformations [125c,f]. 

Depending on the types of unsaturated functional units involved in the metathesis process, the reactions can be classified into three major categories diene, enyne, and diyne metathesis (Figs. 1-3). Another mode of classification... 

Guanacastepene A (444) is a novel tricyclic diterpene with fused five-, seven-, and six-membered rings. The possibility of constructing polycyclic compounds via tandem RCM of dienynes was used in Hanna s synthesis of a highly functionalized tricyclic system 443 related to 444. Under the conditions outlined in Scheme 87, trienyne 440 provided the desired tricycle 442 in a single step, as a result of sequential enyne RCM followed by RCM of intermediate 441. Compound 442 was then further functionalized to 443 [182]. 

As predicted from the comparative rates for C=C over C=C hydrozirconation cited earlier, a (poly)enyne is selectively hydrozirconated at the alkyne moiety, whatever the position of the alkene function [138, 210] in the molecule. It can be exempUfied by the chemoselective hydrozirconation of 1,3-butenyne. One exception to this chemoselectivity has been reported, which showed the terminal alkene to react with 1 but leaving the TMS-substituted alkyne function intact (Scheme 8-25). 

It is interesting to note that a copper(II)-mediated coupling reaction of alkenyldialkyl- or trialkylboranes with alkynylcopper compounds, generated in situ, in the presence of various solvents and a small amount of water, gives (E)-l,3-enynes (or disubstituted alkynes) with various functional groups in reasonable yields (Eq. 4.3).12... 

Scheme 20 Mechanism, functional group compatibility, and selectivity within enyne cy-clizations catalyzed by 70 Cy = cyclohexyl...

Synthesis of Functionalized Enynes by Palladium/Copper-catalyzed Coupling Reactions of Acetylenes with (Z)-2,3-Dibromopropenoic Acid Ethyl Ester (Z)-2-Bromo-5-(trimethylsilyl)-2-penten-4-ynoic Acid Ethyl Ester. 

The formation of a six-membered ring is also feasible but is more limited, and the reaction is found to be more sensitive to the reaction conditions (Scheme 51). The difficulty for forming cyclohexanes is ascribed to the poorer ability of 1,7-enynes to function as bidentate ligands. This problem can be partially circumvented by introducing an alkene moiety (206 vs. 207) or a substituent that can coordinate to the metal, such as a free carboxylic acid, although in this case, the actual mechanism involves hydropalladation as the first step (see Section 10.07.4.1.3.(i).). 

These transformations take advantage of the knowledge obtained from well-established intermolecular reactions (metal-catalyzed hydrosilylation, borostannylation, etc.) and operate in a way that functionalizes both ends of the two unsaturated partners (enyne in this section) in the same manner as in the parent intermolecular reaction.264,265... 

The stereocontrol and functional group tolerance exhibited by the palladium-catalyzed silane-mediated reductive enyne cyclization has led to its use as a key bond formation en route to structurally complex natural products. These include /3-necrodol,59 (—)-4a,5-dihydrostreptazolin,S9b ( )-laurene,S9c and, as illustrated by the conversion of 1,6-enyne 35a to furan 35b, ( )-phyllanthocin (Scheme 25).S9a... 

A hydrosilylation/cyclization process forming a vinylsilane product need not begin with a diyne, and other unsaturation has been examined in a similar reaction. Alkynyl olefins and dienes have been employed,97 and since unlike diynes, enyne substrates generally produce a chiral center, these substrates have recently proved amenable to asymmetric synthesis (Scheme 27). The BINAP-based catalyst employed in the diyne work did not function in enyne systems, but the close relative 6,6 -dimethylbiphenyl-2,2 -diyl-bis(diphenylphosphine) (BIPHEMP) afforded modest yields of enantio-enriched methylene cyclopentane products.104 Other reported catalysts for silylative cyclization include cationic palladium complexes.105 10511 A report has also appeared employing cobalt-rhodium nanoparticles for a similar reaction to produce racemic product.46... 

Under a pressure (20 bar) of carbon monoxide, carbonylative silylcarbocyclization of enyne 92 was examined in the presence of a cationic rhodium-BINAP catalyst (Scheme 31).86 Although the enantioselectivity is low, the five-membered carbocycle functionalized with an alkenylsilane moiety and a formyl group was obtained with high selectivity. 

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