Transmetallation acylation

Various polyfunctionalized a,/3-alkynyl ketones were easily prepared from many simple or functionalized terminal alkynes according to a one-pot procedure metallation-transmetallation-acylation (Scheme 13.26) [29]. 

Acyl halides react with organometallic reagents without catalysts, but sometimes the Pd-catalyzed reactions give higher yields and selectivity than the Lincatalyzed reactions. Acyl halides react with Pd(0) to form the acylpalladium complexes 846, which undergo facile transmetallation. 

The Pd-catalyzed coupling of an acyl chloride with benzyl chloride to form the benzyl ketone 854 proceeds in the presence of an excess of Zn. In this reaction, benzyl chloride reacts with Zn to form benzylzinc, which undergoes transmetallation with acylpaliadium complex[729]. The reaction has been applied to the synthesis of riccardin B (855)[730]. 

Ketones can be prepared by trapping (transmetallation) the acyl palladium intermediate 402 with organometallic reagents. The allylic chloride 400 is car-bonylated to give the mixed diallylic ketone 403 in the presence of allyltri-butylstannane (401) in moderate yields[256]. Alkenyl- and arylstannanes are also used for ketone synthesis from allylic chlorides[257,258]. Total syntheses of dendrolasin (404)f258] and manoalide[259] have been carried out employing this reaction. Similarly, formation of the ketone 406 takes place with the alkylzinc reagent 405[260],... 

The lithium enolate 2a (M = Li ) prepared from the iron propanoyl complex 1 reacts with symmetrical ketones to produce the diastercomers 3 and 4 with moderate selectivity for diastereomer 3. The yields of the aldol adducts are poor deprotonation of the substrate ketone is reported to be the dominant reaction pathway45. However, transmetalation of the lithium enolate 2a by treatment with one equivalent of copper cyanide at —40 C generates the copper enolate 2b (M = Cu ) which reacts with symmetrical ketones at — 78 °C to selectively produce diastereomer 3 in good yield. Diastereomeric ratios in excess of 92 8 are reported with efficient stereoselection requiring the addition of exactly one equivalent of copper cyanide at the transmetalation step45. Small amounts of triphcnylphosphane, a common trace impurity remaining from the preparation of these iron-acyl complexes, appear to suppress formation of the copper enolate. Thus, the starting iron complex must be carefully purified. 

Conducting the aldol reaction at temperatures below —78 "C increases the diastereoselectivity, but at the cost of reduced yields45. Transmetalation of the lithium enolate 2 a by treatment with diethylaluminum chloride generated an enolate species that provided high yields of aldol products, however, the diastereoselectivity was as low as that of the lithium species45. Pre treatment of the lithium enolate 2a with tin(II) chloride, zinc(II) chloride, or boron trifluoridc suppressed the aldol reaction and the starting iron-acyl complex was recovered. 

In all these reactions, the acylating reagent reacts with the active Pd(0) catalyst to give an acyl Pd(II) intermediate. Transmetallation by the organoboron derivative and reductive elimination generate the ketone. 

Scheme 1.26. Acylation of organoalanes generated in situ by Zr-to-AI transmetallation...

Thus, (i) electron transfer from Pd(0) to cyclohexenone, for example, (ii) Pd—allyl complex formation, (iii) transmetalation forming an acylpalladium complex, and (iv) reductive elimination of Pd(0), would give either a 1,2- or a 1,4-acylation product [26] (Scheme 5.21). The role of the triphenylphosphane ligand in the regioselective formation of a 1,2-acylation product may be explained by the preferred formation of a stereochemically less crowded intermediate complex A (Scheme 5.22) and subsequent reductive elimination of Pd(0). 

The addition of carbonyl compounds towards lithiated 1-siloxy-substituted allenes does not proceed in the manner described above for alkoxyallenes. Tius and co-work-ers found that treatment of 1-siloxy-substituted allene 67 with tert-butyllithium and subsequent addition of aldehydes or ketones led to the formation of ,/i-unsaturated acyl silanes 70 (Scheme 8.19) [66]. This simple and convenient method starts with the usual lithiation of allene 67 at C-l but is followed by a migration of the silyl group from oxygen to C-l, thus forming the lithium enolate 69, which finally adds to the carbonyl species. Transmetalation of the lithiated intermediate 69 to the corresponding zinc enolate provided better access to acylsilanes derived from enolizable aldehydes. For reactions of 69 with ketones, transmetalation to a magnesium species seems to afford optimal results. 

Also in the case of intennediate 374, a lithium-copper transmetallation with a copper(I) halide (bromide or chloride) allowed one to carry out the conjugate addition [to electrophilic olefins R CH = CH2Z (Z = COR, CO2R) giving compounds 381 in 31-76% yield], the acylation (with acyl chlorides yielding ketones 382 in 35-65% yield) and dimerization [using copper(II) chloride as the additive, to give compound 383 in 59% yield] processes ... 

In the following year, this method was also applied to the total synthesis of tjipanazole FI (371) (784). For this synthesis, the required bisindole 1444 was obtained starting from 5-chloroindole (1440) in three steps and 47% overall yield. Acylation of 1440 with oxalyl chloride led to the glyoxylic acid chloride 1441. Transmetalation of indolylmagnesium bromide with zinc chloride, followed by addition of the acid chloride, provided the ot-diketone 1443. Exhaustive reduction of 1443 with lithium aluminum hydride (LiAlFl4) afforded the corresponding bisindolylethane 1444. Executing a similar reaction sequence as shown for the synthesis of tjipanazole F2 (372) (see Scheme 5.243), the chloroindoline (+ )-1445 was transformed to tjipanazole FI (371) in two steps and 50% overall yield (784) (Scheme 5.244). 

Treatment of lithium enolate species, such as 7, with a variety of metal halide species produces enolates with different reactivities in particular, diethylaluminum(IH) and copper(I) species have been found to profoundly alter stereodifferentiation in reactions of iron acyl enolates (see Section D.1.3.4.2.5.1.). It has not been established whether complex formation or discrete ti ansmetalation occurs usually, a temperature increase from — 78 °C to — 42 °C is required for maximum effect, suggesting that cation exchange is responsible. In some cases, such additives exert an influence at —78 °C13, and this has been attributed to simple Lewis acid-type interactions with the substrate instead of transmetalation of the enolate species. For simplicity, when such additives are allowed to react with enolate species at temperatures of — 42 =C and above prior to the addition of other reagents, the process shall be referred to as transmetalation. 

Other magnesium allenyl enolates, such as 22, obtained by transmetallation of the lithium species have been used successfully in the preparation of a,-unsaturated acyl silanes (equation 28). ... 

---