I don't have a full solution, but I do have a reduction that can be used as a first step. First, decompose the graph into its biconnected components. This decomposition identifies all the cut vertices, a vertices that, if removed, disconnects the graph into two components. For each cut vertex, the source and destination vertex pairs are either on the same side of the cut, as a non-split pair, or on opposite sides of the cut, as a split pairs. (If the cut vertex is also either source or target, count it as a split pair.)

If there are two or more split pairs for any cut vertex, the problem has no solution, because both paths would have to pass through the cut vertex. (This is a generalization of the quincunx graph example in my comment above.)

If there are no split pairs, then the problem resolves into two smaller problems, one on each of the components. The solution is the combination of a solution on each of the smaller ones.

If there is exactly one split pair, then you reduce the problem to pair of smaller problems, one on a related version of each of the components, where the cut vertex is duplicated between the graphs. Suppose the cut vertex is `X_1`

in some component; in that component label the duplicated cut vertex `Y_1`

. Vice-versa for the other component. As before, the solution is a combination of that of the two smaller ones.

The essence of this solution is the pigeonhole principle, since two paths can't go through one point. Moving up one step, three points can't go through two points. This leads immediately to examining triconnected components and using SPQR trees. From this structure, you can enumerate all two-point cuts. As before divide, the vertices into two sets and proceed analogously, except that you have to consider all permutations of the split pairs. The subproblems are now all on triconnected components.

You can see where this leads. I don't know if SPQR trees have been generalized to higher degrees of connectivity. Even if they have been, you can expect combinatorial explosion in general. And all this leads to a hard problem.

At first, I suspected the problem was tractable on planar graphs. It's not; see the paper referenced above. It remains NP-complete.

Given the above algorithm, you can assume a problem on a biconnected graph. The difference here is that planar graphs only have "local" edges (seen by embedding the graph on a sphere); "remote" edges would have to cross others. That means that behavior of minimal cut sets is much more well behaved. But not enough more well behaved to make the problem work.