Is it faster to count down than up?
Maybe. But far more than 99% of the time it won't matter, so you should use the most 'sensible' test for terminating the loop, and by sensible, I mean that it takes the least amount of thought by a reader to figure out what the loop is doing (including what makes it stop). Make your code match the mental (or documented) model of what the code is doing.
If the loop is working it's way up through an array (or list, or whatever), an incrementing counter will often match up better with how the reader might be thinking of what the loop is doing - code your loop this way.
But if you're working through a container that has
N items, and are removing the items as you go, it might make more cognitive sense to work the counter down.
A bit more detail on the 'maybe' in the answer:
It's true that on most architectures, testing for a calculation resulting in zero (or going from zero to negative) requires no explicit test instruction - the result can be checked directly. If you want to test whether a calculation results in some other number, the instruction stream will generally have to have an explicit instruction to test for that value. However, especially with modern CPUs, this test will usually add less than noise-level additional time to a looping construct. Particularly if that loop is performing I/O.
On the other hand, if you count down from zero, and use the counter as an array index, for example, you might find the code working against the memory architecture of the system - memory reads will often cause a cache to 'look ahead' several memory locations past the current one in anticipation of a sequential read. If you're working backwards through memory, the caching system might not anticipate reads of a memory location at a lower memory address. In this case, it's possible that looping 'backwards' might hurt performance. However, I'd still probably code the loop this way (as long as performance didn't become an issue) because correctness is paramount, and making the code match a model is a great way to help ensure correctness. Incorrect code is as unoptimized as you can get.
So I would tend to forget the professor's advice (of course, not on his test though - you should still be pragmatic as far as the classroom goes), unless and until the performance of the code really mattered.