For the modified question, here is a counter-example: 

First, note that the Cantor set $K$ is (topologically) homogeneous: the group of homeomorphisms acts transitively. (One way to see this is by observing that the group $\widehat {\mathbb Z}_p$ is homeomorphic to the Cantor set.) Now, let $X$ denote the suspension of  $K$; concretely, if $K$ is embedded in $\mathbb R\times \{0\}\subset \mathbb R^2$, then $X$ is the double cone over $K$ from the points $(0,1)$ and $(0,-1)$. Thus, $X$ is planar and every self-homeomorphism of $K$ extends to a self-homeomorphism of $X$. On the other hand, self-homeomorphisms of $K$ do not preserve "boundary" points (since $Homeo(K)$ acts transitively), where the "boundary" $B(K)$ is understood as the union of boundary points of complementary intervals. Hence, $Homeo(X)$ does not send $B(X)$ to $B(X)$ either. Here $B(X)$ is understood as in your question: union of boundaries of complementary components of $X$. 

This example, of course, is not locally connected. There are locally connected examples as well, but they are more complicated, limit sets of certain convex-cocompact Kleinian groups. Here is a sketch. Start with a compact surface $S$ of genus $g\ge 1$ and one boundary component. Now, glue four copies of $S$ ($S_1,...,S_4$) along their boundaries. The result is a complex $W$. Let $F_i$ denote the subsurfaces $S_i\cup S_{i+1}$, $i$ is taken mod $4$, in $W$. 
Let $\pi$ be its fundamental group. One proves that $\pi$ is isomorphic to a convex-cocompact subgroup $\Gamma< PSL(2,\mathbb C)$. Let $X\subset S^2$ denote the limit set of $\Gamma$. It is a Peano continuum. Up to relabelling and conjugation, peripheral subgroups of $\Gamma$ (stabilizers of components of the domain of discontinuity of $\Gamma$) are $\pi_1(F_1)$, ... $\pi_1(F_4)$. But there is an obvious homeomorphism of $W$ which sends $S_1$ to itself and swaps $S_3$ and $S_2$. The corresponding homeomorphism $h$ of the limit set $X$ will not preserve $B(X)$: The image of the limit set of $\pi_1(F_1)$ under $h$ will not  be contained in $B(X)$. This is a "reincarnation" of an exotic self-homeomorphism of the bipartite graph with two vertices and four edges embedded in the plane.