It is well known that $\mathbf{PGL}_2(\mathbb{Z})$ is finitely generated, and that $\mathbf{PGL}_2(\mathbb{Q})$ isn't. My question is: what is a fast, natural way to see these properties without explicit construction of generators?
For instance, do (some) generating properties of an integral domain (or division ring) $D$ carry over to $\mathbf{PGL}_2(D)$?
For $PGL_2(\mathbb{Z})$, you can use general properties of arithmetic groups due to Borel and Harish-Chandra, which will carry over to rings of $S$-integers of number fields. Alternatively, you can inspect the Smith Normal Form (aka elementary divisors) algorithm to obtain finite generation, which carries over to PIDs.
For $PGL_2(\mathbb{Q})$, note that every finitely generated subgroup is contained in $PGL_2(R)$ where $R$ is the subring generated by the entries of the generators, but $\mathbb{Q}$ is not finitely generated as a ring. This carries over to other rings that are not finitely generated. Alternatively, you can use the surjection given by the determinant $PGL_2(\mathbb{Q}) \to \mathbb{Q}^\times/(\mathbb{Q}^\times)^2$, where the target group is not finitely generated. This carries over to rings with infinitely generated group of units modulo squares.
This is surely a matter of taste, but for me the fastest way to see that $PGL_2(\mathbb{Z})$ is finitely generated is to observe that it acts on the tree dual to the Farey graph with finite stabilizers and finite (i.e. compact) quotient. Therefore the Milnor–Schwarz Lemma implies that it is finitely generated.
Implicit in this, as Lee suggests, is a natural output of a choice of generators for any compact fundamental domain for the action.
