I learned from Kip Irvine's book. If you ignore the (fair) criticisms of his (irrelevant) libraries, I can recommend it as a good introduction to the language itself -- although for the really interesting stuff you have to hunt out obsessives on the net.
I think it's useful to understand what happens at the lower levels. As you research assembler you will learn about cpu pipelining, branch prediction, cache alignment, SIMD, instruction reordering and so on. Knowledge of these will help you write better high-level code.
Furthermore, the conventional wisdom is to not try to hand-optimise assembly most of the time but let the compiler worry about it. When you see some examples of the twisted things that compilers generate, you will better understand why the conventional wisdom holds.
Example: LFSRs run fast with the rotate-with-carry instruction, for specific cases like this it's just as easy to write the assembler version as it is to discover whether or not the compiler is smart enough to figure it out. Sometimes you just know something that the compiler doesn't.
It also increases you understanding of security issues -- write-or-execute, stack overruns, etc.
Some concurrency issues only become apparent when you are aware of what is happening at the per-instruction level.
It can be useful sometimes when debugging if you don't have the complete source code.
There's the curiousity value. How are virtual functions implemented anyway? Ever try to write DirectX or COM programs in assembler? How do large structures get returned, does the calling function offer a space for them or vice-versa?
Then there are special assembly languages for graphics hardware, although shader languages went high-level a few years ago, anything which lets you think about a problem a different way is good.