Kernel of Jordan Normal Form

Let $J_{mtimes m} $ be the Jordan normal form with real $c$ on the diagonal and 1 on the super diagonal. Show that

$$null (J-cI) subset null (J-cI)^2 subset … subset null(J-cI)^{m-1} subset null (J-cI)^m $$

I was wondering if there is a shorter and alternative proofs than the one I managed to come up with.

The proof goes as follows:

Since $J$ is a Jordan normal form,
$exists x_m : (J-cI)^m x_m = 0$ and $(J-cI)^{m-1} x_m neq 0$.

By induction on m,

Base case $r=2$ then if $$k in null (J-cI) \
(J-cI)k = 0 \
(J-cI)^2= (J-cI)(J-cI) k = 0 $$
so $k in null (J-cI)^2 $
But since $exists x_m : (J-cI)^{m-1} x_m neq 0 $ then
$x_2 = (J-cI)^{m-2} x_m$ and $x_2 in null (J-cI)^2$ and $x_2 notin null (J-cI)$ thus a strict subset.

Suppose true for r=m-1 i.e
$$null (J-cI) subset null (J-cI)^2 subset … subset null(J-cI)^{m-1}$$

Then for $k in null (J-cI)^{m-1}$, by similar procedure $k in null (J-cI)^m$ and $x_m in null (J-cI)^m, x_m notin null(J-cI)^{m-1} $ so a strict subset.

So the proposition is true by mathematical induction.

Main question is whether there’s a more direct method of proving this?