Thiazolines oxazolines

This metal-directed ring-opening of thiazolines, oxazolines and related compounds is a widespread reaction. In many cases, equilibria are set up between the heterocyclic compound and the imine. The position of these equilibria are metal-ion dependent. A typical example is seen in Fig. 5-81. The reaction of 2-(2-pyridyl)benzothiazoline (5.36) with copper(n) salts leads to the formation of complexes of the ring-opened tridentate form. 

The use of metallated thiazoles, thiazolines, oxazolines, and dihydrooxazines as anion-equivalents in organic syntheses has been advanced extensively [1-6]. Table 7 summarizes the conditions for preparative metallations of a numbers of substituted heterocycles. 

The chiral catalysts that have been used in nitroaUcene conjugate additions include bw-oxazolines with Cu(OTF)2 [281] or Zn(OTf)2 [282], tridentate bw-oxazolines with Zn(OTf)2 [283], mixed thiazoline-oxazolines with Zn(OTf)2 [284], imidazoUne-aminophenols with CuOTf [285], bis-trifluoromethylsulfonamides [286], binaphthyl sulfonamides [287], binaphthyl imines [288], thioureas [289], and quinoUnyl thioureas [290]. A BINOL-phosphoric acid with 3A molecular sieves gave ee values consistently at 90% and above with both p-alkyl and p-aryl nitroalkenes [291]. 

Thioacetyl derivatives (155) are obtained by direct heterocyclization reactions (365. 378, 563) and by a sulfur-oxygen exchange" reaction involving thioacetic acid and A-2-oxazoline-5-one (154) or A-2-thiazoline-5-one (156) (Scheme 81) (365, 378, 379). Ra-Ni reduction of 155 affords the 5-unsubstituted thiazole (379). 

A-2-Oxazoline-5-one (2091 when treated with thioacetic acid yields the corresponding thiazoline-5-one (210) (Scheme 107) (458. 461). These results have been questioned recently (365) however, it appears in the later report that a large excess of thioacetic acid was used instead o-f the stoichiometric amount previously used. 

A -Imidazolines, -oxazolines and -thiazolines (291), and their benzo derivatives (292), are very easily aromatized (292 293), and syntheses which might be expected to yield... 

A -Imidazolines (294 Z = NH) are cyclic amidines and exhibit the characteristic resonance stabilization and high basicity. A -Oxazolines (294 Z = 0) are cyclic imino ethers, and A"-thiazolines (294 Z = S) are imino thioethers both are consequently easily hydrolyzed by dilute acid. 

Many mercaptoazoles exist predominantly as thiones. This behavior is analogous to that of the corresponding hydroxyazoles (c/. Section 4.02.3.7). Thus oxazoline-, thiazoline- and imidazoline-2-thiones (521) all exist as such, as do compounds of type (522). However, again analogously to the corresponding hydroxyl derivatives, other mercaptoazoles exist as such. 5-Mercaptothiazoles and 5-mercapto-l,2,3-triazoles (523), for example, are true SH compounds. 

In contrast to the above additions A-allyl- and substituted A-allyl-amides, -urethanes, -ureas and -thioureas undergo intramolecular cyclization only in 6(3-96% sulfuric acid to give the corresponding oxazolinium and thiazolinium salts. Treatment of these cations with base yields 2-oxazolines and 2-thiazolines in moderate to good yields. The reaction is illustrated by the conversion of A-2-phenylallylacetamide (342) into 2,5-dimethyl-5-phenyl-2-oxazoline (343) in 70% yield 70JOC3768) (see also Chapter 4.19). 

The photochemical addition of azirines to the carbonyl group of aldehydes, ketones, and esters is also completely regiospecific (77H(6)143). Besides the formation of the isomeric oxazolines (50) from (39) and ethyl cyanoformate, there is also formed the imidazole (51) from addition to C=N in the expected regioselective manner. Thioesters lead to thiazolines (52), while isocyanates and ketenes produce heterocycles (53). 

A direct conversion of the oxazoline (44) to the thiazoline (45) can be achieved by the thiolysis of the oxazoline (44) with H2S in methanol in the presence of triethylamine followed by cyclodehydration with Burgess reagent. This method is essentially free from racemisation and has been used in the transformation of peptide substrates <95TL6395>. 

In 2004, ruthenium-catalysed asymmetric cyclopropanations of styrene derivatives with diazoesters were also performed by Masson et al., using chiral 2,6-bis(thiazolines)pyridines. These ligands were prepared from dithioesters and commercially available enantiopure 2-aminoalcohols. When the cyclopropanation of styrene with diazoethylacetate was performed with these ligands in the presence of ruthenium, enantioselectivities of up to 85% ee were obtained (Scheme 6.6). The scope of this methodology was extended to various styrene derivatives and to isopropyl diazomethylphosphonate with good yields and enantioselectivities. The comparative evaluation of enantiocontrol for cyclopropanation of styrene with chiral ruthenium-bis(oxazolines), Ru-Pybox, and chiral ruthenium-bis(thiazolines), Ru-thia-Pybox, have shown many similarities with, in some cases, good enantiomeric excesses. The modification... 

It is worth mentioning here that the spirocyclopropyl-substituted oxazoline-5-car-boxylates 2-172, as well as the corresponding thiazoline-4-carboxylates, can be transformed into cyclopropyl-substituted amino acids, which might act as potential enzyme inhibitors [93] and interesting building blocks for peptidomimetics [94]. 

In NRPs and hybrid NRP-PK natural products, the heterocycles oxazole and thiazole are derived from serine and cysteine amino acids respectively. For their creation, a cyclization (or Cy) domain is responsible for nucleophilic attack of the side-chain heteroatom within a dipeptide upon the amide carbonyl joining the amino acids [61]. Once the cyclic moiety is formed, the ring may be further oxidized, to form the oxazoline/thiazoline, or reduced, to form oxazolidine/thiazolidine (Figure 13.20). For substituted oxazoles and thiazoles, such as those... 

The C2-symmetric bifunctional tridentate bis(thiazoline) 222 has been shown to promote the zinc(II)-catalyzed asymmetric Michael addition of nitroalkanes to nitroalkenes in high enantioselectivity <06JA7418>. The corresponding bis(oxazoline) ligand provides comparable enantioselectivity but higher product yield. The same bis(thiazoline) ligand has also been evaluated in the enantioselective Friedel-Crafts alkylation of indoles, but the enantioselectivity is moderate <06OL2115>. 

Gu, R.-L., Lee, I.S. and Sih, C.J., Chemo-enzymatic asymmetric synthesis of amino acids. Enantioselective hydrolyses of 2-phenyl-oxazolin-5-ones. Tetrahedron Lett., 1992, 33, 1953-1956 Crich, J., Brieva, R., Marquart, P., Gu, R.-L., Flemming, S. and Sih, C.J., Enzymic asymmetric synthesis of a-amino acids. Enantioselective cleavage of 4-substituted oxazolin-5-ones and thiazolin-5-ones. J. Org. Chem., 1993, 58, 3252-3258. 

The oxidation state of thiazolines and oxazolines can be adjusted by additional tailoring enzymes. For instance, oxidation domains (Ox) composed of approximately 250 amino acids utilize the cofactor FMN (flavin mononucleotide) to form aromatic oxazoles and thiazoles from oxazolines and thiazolines, respectively. Such domains are likely utilized in the biosynthesis of the disorazoles, " diazonimides, bleomycin, and epothiolone. The typical domain organization for a synthetase containing an oxidation domain is Cy-A-PCP-Ox however, in myxothiazol biosynthesis one oxidation domain is incorporated into an A domain. Alternatively, NRPSs can utilize NAD(P)H reductase domains to convert thiazolines and oxazolines into thiazolidines and oxazolidines, respectively. For instance, PchC is a reductase domain from the pyochelin biosynthetic pathway that acts in trans to reduce a thiazolyinyl-Y-PCP-bound intermediate to the corresponding thiazolidynyl-Y-PCP. ... 

The heterocyclic component in the leaving group offers possibilities for introduction of chirality. Optically active oxazolin-2-yl and thiazolin-2-yl allyl thioethers 7 were thus chosen as substrates (Scheme 8.8) [17]. 

Scheme 8.8. Enantioselective substitution of oxazolin-2-yl and thiazolin-2-yl allyl thioethers.

Scheme 46. One-pot preparations of spirocyclopropanated oxazolines 143 and thiazolines 144 from chlorocyclopropylideneacetates 1,2 [53,72,87]...

Meyers and Ford (76JOCI735), and Hirai et al. (72CPB206) have used 2-(alkylthio)-2-oxazolines or thiazolines to prepare the corresponding thi-iranes upon treatment with bases and subsequently with carbonyl compounds. The reactions of 2-pyridyl sulfides are expected to proceed similarly as shown in Scheme 22, since the oxazoline ring is a good leaving group in the intramolecular substitution reaction. When optically active oxazolines are used, asymmetric induction takes place to afford the optically active thiiranes in 19-32% enantiomeric excess (ee). The process is shown in Scheme 23. 

In NRPS, the cyclization domain catalyzes cyclization of the side-chain nucleophile from a dipeptide moiety such as AA-Ser or AA-Cys (AA = amino acids) to form a tetrahedral intermediate, followed by dehydration to form oxazolines and thiazolines (Scheme 7.1) [20]. The synthesis of a 2-methyl oxazoline from threonine follows a similar mechanism. Once a heterocycle is formed, it can be further modified by reductase to form tetrahydro thiazolidine in the case of pyochelin biosynthesis. Conversely, oxidation of the dehydroheterocycles lead to heteroaro-mahc thiazoles or oxazoles as in the case of epothilone D (Figure 7.2) [21]. 

An alternative mechanism to form thiazoles and oxazoles is through oxidation of a dipeptide followed by cyclization from an enolate or thienolate precursor and subsequent dehydration (Scheme 7.2). This represents a higher-energy pathway and there is no accumulation of thiazoline or oxazoline intermediates [22-24]. 

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