Repeatedly taking logs is a nice (usually) generally-applicable solution to problems of this sort. Here's a more special-case approach to this problem: recall that e = lim(n->infinity, (1+1/n)^n). So to be a good approximation to e, all we need is for 9^(4^(42)) (the denominator of the fractional part) to be sufficiently close to 3^(2^85) and big.
In this case, they're identical, so we have n=3^(2^85), and it's going to be a very good approximation to e. These are big numbers, but not unworkably so:
>>> from mpmath import *
>>> iv.dps = 50 # let's use interval arithmetic, just for fun
>>> x = mpi(9)**(-(4**(42)))
>>> up = (mpi(3)**(2**85))
>>> 0 in (1/x-up)
Working out the exact error bounds on e is left as an exercise for the reader ;-) -- hint: compare the number of digits of accuracy the mathworld page claims and the above numbers, and ask why that might be, thinking of the series of approximations (1+1/1)^1, (1+1/2)^2, etc.