(This won't be the most formal proof in the world, but hopefully its good enough to convince yourself).

Lets say for a vertex *v*, in graph *G*, the shortest path from *v* to *k* is of length *m*.
The two things you want to know are:

1. In the reversed graph, G*, there is a path of length *m* from *k* to *v*.

2. In the reversed graph, G*, there are no paths from *k* to *v* that are shorter than *m*.

Before I start, can we take one thing on faith:

*Lemma 1*: If you have a directed path from vertex *v* to vertex *w*, and you reverse every edge on the path, then you have a path from vertex *w* to vertex *v*. This is provable, but I think its fairly common sense. I'll prove it if you want me to.

For point 1: Consider the path in *G* from *v* to *k* consisting of *m* edges. If you reverse each of these edges, you will have a path from *k* to *v* of length *m* (by *Lemma 1*).

For point 2: Suppose there exists a path in the reversed graph G*, from *k* to *v* of length *n* < *m*. If you reverse this path, then there is a path of length *n* from *v* to *k* (*Lemma 1*). This means that there is a path from *v* to *k* in the original graph that is shorter than *m*, contradicting the statement that the path of length *m* is the shortest.