17.3: Double Nucleophilic Acyl Substitution

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Other nucleophiles participate in nucleophilic acyl substitution chemistry, but undergo substitution twice. Let’s illustrate this concept in the context of a multistep synthesis. How would you synthesize the following molecule?

Screen Shot 2023-01-04 at 9.22.57 AM.png

How could we convert the following compound to the tertiary alcohol?

Screen Shot 2023-01-04 at 9.23.02 AM.png

Two possibilities:

Pathway A:

Screen Shot 2023-01-04 at 9.23.08 AM.png

In the first step of this sequence, LAH reduces a carboxylic acid all the way to an alcohol via two successive irreversible nucleophilic acyl substitution mechanisms. This type of double reactivity can occur for both carboxylic acids and esters, or anything to the right in the reactivity series. Let’s take a look:

Screen Shot 2023-01-04 at 9.23.15 AM.png

The product of the first nucleophilic acyl substitution is an aldehyde, and you already know that aldehydes react with LAH to give alcohols. Thus, the next step is also a nucleophilic acyl substitution mechanism which will yield the primary alcohol.

What this tells us is that aldehydes and ketones are more reactive than esters and carboxylic acids, so we can update our reactivity series. This should make sense because resonance is more strongly donating than \(σ\)-donation.

Screen Shot 2023-01-04 at 9.23.21 AM.png

Now, let’s go back to our original question. We could take LAH and reduce the acid to the alcohol, then perform a series of oxidation and Grignard reactions to arrive at the final product, but this would be quite long. Know that some nucleophiles like LAH react twice, can you think of a pathway that might be much shorter?

Pathway B:

Screen Shot 2023-01-04 at 9.23.36 AM.png

If we convert the carboxylic acid to the ester and then use two equivalents of MeMgBr, we can generate the tertiary alcohol in one reaction flask after acidic workup!

Screen Shot 2023-01-04 at 9.23.42 AM.png

The take-home message here is that harder nucleophiles like LAH, RMgBr, and RLi perform nucleophilic acyl substitution, but the product of this step is more reactive than the starting material, so a second nucleophilic acyl substitution occurs rapidly. Overall, the nucleophile has been incorporated twice.

One more thing – MeLi and PhLi will react with carboxylic acids only once because the tetrahedral intermediate is stable. After workup, this intermediate decomposes to give a ketone.

Screen Shot 2023-01-04 at 9.23.51 AM.png

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