vertices on a path

This is a nice proof due to the (undergraduate) book by Bondy and Murty (Theorem 3.2)

I will use the fact that for a nontrivial graph, if the graph is $2$-connected, then the graph is at least $2$-edge-connected; this means that if the graph cannot be disconnected by removing a single vertex, then it cannot be disconnected by removing a single edge either (this is good to prove as an exercise).

We will use induction on $d(u,v)$. I will use the base case of $d(u,v) = 1$; if $d(u,v) = 1$, then if $e$ is the edge joining $u$ and $v$, $G-e$ is connected; so there is a $(u,v)$-path in $G-e$ which, together with $e$, gives a cycle containing $u$ and $v$.

Now we will assume that this holds for any two vertices at distance less than $k$, and assume that $d(u,v) = k geq 2$. Consider a $(u,v)$-path of length $k$, and let $w$ be the vertex that preceeds $v$ on this path. Now $d(u,w) = k-1$, so there is a cycle containing $u$ and $w$; we will consider this cycle $P cup Q$ where $P$ and $Q$ are internally disjoint $(u,w)$-paths. Furthermore, $G-w$ is connected so there is a $(u,v)$ path $P^{prime}$ not containing $w$. Let $x$ be the last vertex in $P^{prime}$ that is also in $P cup Q$; without loss of generality we can assume that $x in P$.

Now we get a cycle containing $u$ and $v$ by following $P$ from $u$ to $x$; following $P^{prime}$ from $x$ to $v$; the edge $vw$; and then $Q$ from $w$ to $u$ (technically I guess we are traversing the path $Q$ backwards).