Hydrogen enantiotopic

It is also possible to achieve enantioselective enolate formation by using chiral bases. Enantioselective deprotonation requires discrimination between two enantiotopic hydrogens, such as in d.v-2,6-dimethylcyclohexanone or 4-(/-butyl)cyclohcxanonc. Among the bases that have been studied are chiral lithium amides such as A to D.22... 

This example is from biochemistry. It is a feature of biochemical reactions that enzymes almost always catalyse reactions in a completely stereospecific manner. They are able to distinguish between enantiotopic hydrogens because of the three-dimensional nature of the binding site (see Section 13.3.2). There are also occasions where chemical reactions are stereospecific refer to the stereochemistry of E2 eliminations for typical examples (see Section 6.4.1). 

For Rh(I)/BINAP-catalyzed isomerizations of allylic amines, the mechanistic scheme outlined in Eq. (2) has been proposed. The available data are consistent with the notion that Rh(I)/PF-P(o-Tol)2-catalyzed isomerizations of allylic alcohols follow a related pathway [11]. For example, the only deuterium-containing product of the reaction depicted in Eq. (9) is the l,3-dideuterated aldehyde, which estabhshes that the isomerization involves a clean intramolecular 1,3-migration. The data illustrated in Eqs. (10) and (11) reveal that the catalyst selectively abstracts one of the enantiotopic hydrogens/ deuteriums alpha to the hydroxyl group. 

What of the two methylene protons in ethanol, 7, which we have labeled as HA HA. Are they identical In a sense they are not identical because, if each were replaced by X, we would have a pair of enantiomers. Therefore, HA and f lA. sometimes are called enantiotopic hydrogens. 

But, you will recall that enantiomers are chemically indistinguishable unless they are in a chiral environment. Therefore we expect shifts of enantiotopic hydrogens to be identical, unless they are in a chiral environment. To summarize, enantiotopic protons normally will have the same chemical shifts, whereas diastereotopic protons normally will have different chemical shifts. 

The symmetry planes (a) in molecules 30, 32, 34, 36, 38, Fig. 13 should be readily evident. It is possible to have both homotopic and enantiotopic ligands in the same set, as exemplified by the case of cyclobutanone (34) HA and HD are homotopic as are HB and Hc, HA is enantiotopic with HB and Hc HD is similarly enantiotopic with Hc and HB. The sets HAjB and HC>D may be called equivalent (or homotopic) sets of enantiotopic hydrogen atoms. The unlabeled hydrogens at position 3, constitutionally distinct — see Section 3.4 — from those at C(2, 4), are homotopic with respect to each other. Enantiotopic ligands need not be attached to the same atom — viz. the case of mew-tartaric acid (32) and also the just-mentioned pair Ha, Hc [or Hb, Hd] in cyclobutanone. 

The most prevalent base-catalyzed reaction of an endoperoxide is the Kornblum-DeLaMare decomposition [97a] which leads to a hydroxy ketone by removal of a proton from the carbon adjacent to the peroxy linkage [9b,90b,97], The formation, in a basic solvent as acetone, of hydroxyfuranones 69 (Sch. 38) in the photo-oxygenation of a,a -unsubstituted furans might occur via a similar rearrangement [60e]. Attempts to induce asymmetry in endoperoxides with enantiotopic hydrogens or with chiral bases have led to moderate success [98]. The Et3N-catalyzed rearrangement of substituted cycloheptatriene endoperoxides 92 leads to... 

Fig. 18. The expected percentages of various labelled products of the dioldehydratase reaction using 25 as substrate. The calculation was based on the following facts and assumptions (1) The enzyme does not differentiate between the enantiotopic hydrogen positions (conclusion from experiments with species 17 and 18 shown in Fig. 14) (2) in the competition between vicinal hydrogen atoms there is an intramolecular kinetic deuterium isotope effect of 2.6 (Fig. 15) (3) this effect is 10 for geminal hydrogen atoms (4) the migrating hydroxyl group substitutes one of the hydrogen atoms in the vicinal position stereospecifi-cally (i.e., with inversion).

Therefore, these two hydrogens are symmetry equivalent (and isochronous) since they are related by reflection in the mirror plane. But because they are not related by any axis of symmetry, they are not homotopic. They are instead referred to as enantiotopic hydrogens, ones related only by a symmetry plane. 

Enantiotopic hydrogens show different reactivity in a chiral environment, and an enzyme is able to distinguish absolutely between them... 

Enantiotopic hydrogens react at identical rates in an achiral environment. In order to bring about a difference in their reactivity, an external chiral influence has to be involved. This can be provided by enzymes, as shown in the following two reactions. 

The mechanism of this isomerization involves an intramolecular 1,3-supra-facial hydrogen migration via an imminium complex 11.21 (Figure 11.6). The enantioselection takes place during the removal of one of the two enantiotopic hydrogen atoms of 11.22, as shown by deuterium labeling experiments (Figure... 

Methylation of amines in nucleotides and proteins plays important roles in biological function. Methyl transferases accept a wide range of nucleophiles such as halides, amines, hydroxyls, and enolates [reactions (a) and (b), Scheme 8.6] [42-44], For example, in the biosynthesis of novobiocin, methylation takes place at only one phenolic carbon and not the remaining three hydroxyl groups [45, 46]. On the other hand, methyl transfer to electron-deficient substrates often occurs under radical mechanisms requiring methylcobalamin as the cofactor, as shown in the biosynthesis of fosfomycin, where only one of the two enantiotopic hydrogen was replaced by the methyl group [reaction (c), Scheme 8.6] [47]. 

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