With a breadth-first search or iterative deepening, I think the mathematical answer to your question involves the notion of a "ball" around a vertex. Define Ball(v, n) to be the set of nodes at distance at most n from node v, and let the distance from the start node s to the destination node t be d. Then in the worst case a forward search will perform better than a backward search if |Ball(s, d)| < |Ball(t, d)|. This is true because breadth-first search always (and ID in the worst case) expands out all nodes of some distance k from the start node before ever visiting any nodes of depth k + 1. Consequently, if there's a smaller number of nodes around the start than the target a forward search should be faster, whereas if there's a smaller number of nodes around the target than the start and backward search should be faster. Unfortunately, it's hard to know this number a priori; you usually either have to run the search to determine which is the case. You could potentially use the branching factor around the two nodes as a heuristic for this value, but it wouldn't necessarily guarantee one search would be faster.
One interesting algorithm you might want to consider exploring is bidirectional breadth-first search, which does a search simultaneously from the source and target nodes. It tends to be much faster than the standard breadth-first search (in particular, with a branching factor b and distance d between the nodes, BFS takes roughly O(bd) time while bidirectional BFS takes O(bd/2)). It's also not that hard to code up once you have a good BFS implementation.
As for depth-first search, I actually don't know of a good way to determine which will be faster because in the worst-case both searches could explore the entire graph before finding a path. If someone has a good explanation about how to determine which will be better, it would be great if they could post it.