This is a bit late, but here is one example I like:
Theorem. A localization of a regular local ring is still regular.
One way to prove is to deduce it from
Theorem. Let $R$ be a local ring. Then the following are equivalent:
$R$ is regular
Every $R$-module has a finite length projective resolution
The residue field has a finite length projective resolution.
(To use it, note that if $R$ is regular, then its residue field has a finite length projective resolution. Now localize--this is exact, so we get a finite length projective resolution over the localization.)
This stuff is in Chapter 19 of Eisenbud's Commutative Algebra.
It's not clear to me how one would try to prove the first theorem from the definitions of regular.