No, consider the map $F_3 \to F_3$ given by
$$
x_1 \mapsto x_1, x_2 \mapsto x_2 [x_1, x_3[x_2, x_1]], 
x_3 \mapsto x_3[x_2, x_1], .
$$
It is an [IA automorphism][1]: it clearly induces the identity map on abelianization. Further, it is an isomorphism because the set $\{ x_1, x_3[x_2, x_1], x_2 [x_1, x_3[x_2, x_1]] \}$ generates and $F_3$ is [Hopfian][2].
 
Further, if you kill $x_3$ (that is, $n = 3$ in the OP's question), then the resulting map under consideration in the question is:
$$
x_1 \mapsto x_1, x_2 \mapsto x_2 [x_1, [x_2, x_1]],
$$
which is clearly not an isomorphism (the word $x_2 [x_1, [x_2, x_1]] = x_2x_1^{-1} (x_2^{-1} x_1^{-1} x_2 x_1) x_1 (x_1^{-1} x_2^{-1} x_1 x_2)$ in reduced form begins and ends with $x_2$).


  [1]: http://groupprops.subwiki.org/wiki/IA-automorphism
  [2]: http://en.wikipedia.org/wiki/Hopfian_group