Another suggestion (which covers containment, and I think is cheaper):

Check if any of the 4 vertices of #1 are inside #2, then check if any of the 4 vertices of #2 are inside #1. Here's how i'd suggest to go about that:

Assume the vertex of #1 you're checking is v, and the 4 vertices of #2 are v1 ... v4. *Inverse-rotate* all 5 vertices by #2's orientation. (to inverse-rotate a vector u by an orientation matrix M, multiply u by M-transposed: M^T u , assuming that in your convention orientation works by left-multiplication.)
The resulting 2nd box, call it #2', is now axis aligned - you can immediately check whether v' is contained in it.

If you found any #1-vertex inside of #2 - stop, you have intersection. Otherwise - continue.

A few optimizations immediately pop to mind (maybe you can store unrotated copies of the vertices in each box? if the sizes are fixed, maybe you can compare them to immediately eliminate one of the possible containments, and save 3 potential tests?) but unless you're applying it on gazillions of box pairs, this test should be cheap enough as is.

Regarding the motion, you can get as deep as you want there - look up 'continuous collision', and see for yourself. (I specifically remember some nice works by Stephane Redon). I whole heartedly believe that no game does any of this fancy stuff: if you are indeed moving extremely fast, you can subdivide your time step and perform collision checks on each position/orientation sub-iteration.

(edit:) There was another discussion right here about that, with nice references.