A* can be applied here, though it might not be the best algorithm.

You'll have to step away from the graph of cities and roads between them. Instead, define a directed graph where partial routes are the nodes and two nodes *x* and *y* are connected iff *y* can be constructed from *x* by adding a single "step" in the original cities graph. The start node is an empty path. The goal node is a path through that visits all cities. (Optimality of this path is guaranteed by the properties of the heuristic and the A* algorithm itself.)

[**EDIT**: At first I thought a path should be an ordered list of cities, but I now believe @spinning_plate's suggestion of representing the path by a pair (length, set of cities) is enough.]

The path cost is the total distance travelled. The heuristic would have to be some *admissible* estimate (usually, an underestimate) of the total *minimal* travel length.

A good candidate for such an estimate might be a fast approximation of the TSP (the solution of a *relaxed problem*). You'd run the approximation algorithm for each node (partial route), on the set of cities not yet covered. That gives the algorithm the necessary upper bound on the distance the salesman still has to go.