CSA Group

PhCH(OCH2CH2CH=CH2)2, CSA, NBS. Standard methods failed because of cleavage of the dispiroketal (dispoke) protective group. 

The synthesis of the right-wing sector, compound 4, commences with the prochiral diol 26 (see Scheme 4). The latter substance is known and can be conveniently prepared in two steps from diethyl malonate via C-allylation, followed by reduction of the two ethoxy-carbonyl functions. Exposure of 26 to benzaldehyde and a catalytic amount of camphorsulfonic acid (CSA) under dehydrating conditions accomplishes the simultaneous protection of both hydroxyl groups in the form of a benzylidene acetal (see intermediate 32, Scheme 4). Interestingly, when benzylidene acetal 32 is treated with lithium aluminum hydride and aluminum trichloride (1 4) in ether at 25 °C, a Lewis acid induced reduction takes place to give... 

The completion of the synthesis of key intermediate 2 requires only a straightforward sequence of functional group manipulations. In the presence of acetone, cupric sulfate, and camphorsulfonic acid (CSA), the lactol and secondary hydroxyl groups in 10 are simultaneously protected as an acetonide (see intermediate 9). The overall yield of 9 is 55 % from 13. Cleavage of the benzyl ether in 9 with lithium metal in liquid ammonia furnishes a diol (98% yield) which is subsequently converted to selenide 20 according to Grie-co s procedure22 (see Scheme 6a). Oxidation of the selenium atom... 

Contained within intermediate 25 is an acid-labile mixed acetal group and it was found that treatment of 25 with camphorsulfonic acid (CSA) results in the formation of dioxabicyclo[3.3.0]octane 26 in 77 % yield. Acid-induced cleavage of the mixed cyclic acetal function in 25, with loss of acetone, followed by intramolecular interception of the resultant oxonium ion by the secondary hydroxyl group appended to C leads to the observed product. Intermediate 26 clearly has much in common with the ultimate target molecule. Indeed, the constitution and relative stereochemistry of the dioxabicyclo[3.3.0]octane framework in 26 are identical to the corresponding portion of asteltoxin. 

When a solution of 25 in a 1 1 mixture of methanol and methylene chloride is exposed to periodic acid, the dithiane group is cleaved oxidatively to give, after treatment of the crude product with camphorsulfonic acid (CSA) in methanol, bisacetal 12 as a 2 1 mixture of C-12 anomers in a yield of 80% (Scheme 3). Although the conversion of 12 into 10 could be carried out on the mixture of anomers, it was found to be more convenient to carry each isomer forward separately. When 12 is treated with lithium diethylamide, the methine hydrogen adjacent to the lactone carbonyl is removed as a proton to give an enolate which is then oxidized in a completely diastereoselective fashion with Davis s oxaziridine18 to afford 11. 

The hydroxylation reaction, whose stereochemical course is controlled by the strong inherent preference for the formation of a cis-fused 5,5 ring system, creates a molecule which would appear to be well suited for an intramolecular etherification reaction to give ring E of ginkgolide B (1). Indeed, when a solution of 11 in methylene chloride is exposed to camphorsulfonic acid (CSA), a smooth cycli-zation reaction takes place to give intermediate 10 in an overall yield of 75% from 12. The action of CSA on 11 produces a transient oxonium ion at C-12 which is intercepted intramolecularly by the proximal hydroxyl group at C 4. 

The oxirane ring in 175 is a valuable function because it provides a means for the introduction of the -disposed C-39 methoxy group of rapamycin. Indeed, addition of CSA (0.2 equivalents) to a solution of epoxy benzyl ether 175 in methanol brings about a completely regioselective and stereospecific solvolysis of the oxirane ring, furnishing the desired hydroxy methyl ether 200 in 90 % yield. After protection of the newly formed C-40 hydroxyl in the form of a tert-butyldimethylsilyl (TBS) ether, hydrogenolysis of the benzyl ether provides alcohol 201 in 89 % overall yield. 

The completion of the synthesis of key intermediate 86 only requires some straightforward manipulations. Differential protection of the two hydroxyl groups in 123 can be easily achieved. Selective silylation of the primary hydroxyl with ieri-butyldiphenylsilyl chloride provides, after /ert-butyldimethylsilylation of the remaining secondary hydroxyl, compound 124 (95% overall yield). Acet-onide protecting groups can usually be removed under acidic conditions, and the one present in 124 is no exception. Treatment of a solution of 124 in CFhC MeOH (1 1) at 0°C with CSA... 

With ring G in place, the construction of key intermediate 105 requires only a few functional group manipulations. To this end, benzylation of the free secondary hydroxyl group in 136, followed sequentially by hydroboration/oxidation and benzylation reactions, affords compound 137 in 75% overall yield. Acid-induced solvolysis of the benzylidene acetal in 137 in methanol furnishes a diol (138) the hydroxy groups of which can be easily differentiated. Although the action of 2.5 equivalents of tert-butyldimethylsilyl chloride on compound 138 produces a bis(silyl ether), it was found that the primary TBS ether can be cleaved selectively on treatment with a catalytic amount of CSA in MeOH at 0 °C. Finally, oxidation of the resulting primary alcohol using the Swem procedure furnishes key intermediate 105 (81 % yield from 138). 

Insoluble chitin 2211 is readily silylated by HMDS 2 and Me3SiCl 14 to form the soluble, much more lipophilic 2212, whose 6-silyloxy groups can either be tri-tylated with PhsCCl or glycosylated with the peracetylated oxazolidine 2213, derived from D-glucosamine, in C1(CH2)2C1 in the presence of camphorsulfonic acid (CSA) to give, on work-up with methanol, the branched chitin 2214 in high yields [22] (Scheme 14.8). 

Calcineurin is a heterodimer consisting of a large calmodulin-binding catalytic subunit A (61 kDa) anda Ca2+-dependent subunit B (19 kDa).A diazo-group containing photoreactive CsA (47, Fig. 16) was prepared after binding to cyclophylin and after incubation with calcineurin. Irradiation resulted in specific cross-linking mainly to the subunit B , with some minor interaction to subunit A . 

A cytosolic binding protein for CsA was first isolated in 1984 and named cyclophilin, later cyclophilin A (CyPA), in reference to its high affinity for CsA (18). CyPA is a basic, abundant protein with a mass of 18 kDa, and it is found in a variety of tissues. The first clue to its function came in 1989 when two independent groups isolated the enzyme that catalyzes pepti-dyl proline isomerization/peptidylprolyl cis-trans isomerase (EC 5.2.1.8 PPIase), in protein chains and (re)discovered CyPA (19, 20). CyPA is a potent PPIase, and its enzymatic activity is strongly inhibited by CsA. 

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