OK, since you asked me to post an answer….
Before you understand A*, you must first understand Dijkstra's algorithm. Given a graph (a set of nodes, and edges between nodes) and the (positive) "distance" of each edge (e.g. the road distance), Dijkstra's algorithm gives the shortest distance between a certain source node and each destination node. For instance, in your graph, the nodes may be road-intersections, the edges may be the roads, and the weight/distance you put on an edge may be the length of that road, or the time it takes to traverse it, or whatever.
Please understand: Dijkstra's algorithm always gives the correct distance according to the weights you have put on the edges. In fact, the graph need not even be embeddable in a plane, i.e., there may be no notion of "straight line distance" in the first place. It can be any arbitrary graph.
Now, A* can be thought of as a particular heuristic to speed up Dijkstra's algorithm. You can think of it as using a heuristic to decide the order in which to consider nodes in the graph.
Formally: you have a graph G, two nodes s and t in it, and you want to find the distance d(s,t) between s and t. (The distance is according to the graph, e.g. according to road distance in your example.) To find d(s,t), in A* you use a heuristic function h(x) which satisfies h(x) ≤ d(x,t). For instance (just one possibility), you can choose h(x) to be the straight line distance from x to t. The better h(x) is as an estimate of d(x,t), the faster the A* algorithm will run, but the choice of h affects only the speed, not the answer: it will always give the shortest distance according to d, not h.
So to find the road distance s to t, just set d(u,v) to be the road distance for every pair of nodes u and v with a road between them, run A*, and you'll find the d(s,t) you want.