The most common reason for problems in the absence of a 'volatile' qualifier is that compilers will often place local variables into registers. These registers will almost certainly be used for other things between the setjmp and longjmp. The most practical way to ensure that the use of these registers for other purposes won't cause the variables to hold the wrong values after the longjmp is to cache the values of those registers in the jmp_buf. This works, but has the side effect that there is no way for the compiler to update the contents of the jmp_buf to reflect changes made to the variables after the registers are cached.
If that were the only problem, the result of accessing local variables not declared volatile would be indeterminate, but not Undefined Behavior. There's a problem even with memory variables, though, which thiton alludes to: even if a local variable happens to be allocated on the stack, a compiler would be free to overwrite that variable with something else any time it determines that its value is no longer needed. For example, a compiler could identify that some variables are never 'live' when a routine calls other routines, place those variables shallowest in its stack frame, and pop them before calling other routines. In such a scenario, even though the variables existed in memory when setjmp() is called, that memory might have been reused for something else like holding return address. As such, after the longjmp() is performed, the memory would be considered uninitialized.
Adding a 'volatile' qualifier to a variable's definition causes storage to be reserved exclusively for the use of that variable, for as long as it is within scope. No matter what happens between the setjmp and longjmp, provided control has not left the scope where the variable was declared, nothing is allowed to use that location for any other purpose.