Let $Mod(M)=\pi_0\left(\text{Home(M)}\right)$ be the mapping class group of a manifold, possibly with boundary (I'm including the orientation reversing classes).
Let $P$ be a $1-$sided, embedded $\mathbb{RP}^2$ in $\mathbb{RP}^3$. Its tubular neighborhood is denoted by $\nu(\mathbb{RP}^2)$ and it is a twisted $I-$bundle over $\mathbb{RP}^2$. The boundary $\partial \nu \mathbb{RP}^2$ is an embedded sphere, hence $\mathbb{RP}^3 = \nu(\mathbb{RP}^2) \bigcup_{S^2} \mathbb{B}^3$. 


I know that $\nu(\mathbb{RP}^2) \subset \mathbb{RP}^3$ equals to the quotient $\left(S^2 \times I\middle)\right/_\sim$ with $(x,1)\sim(-x,1)$ thus $\nu(\mathbb{RP}^2) \setminus \mathbb{RP}^2 = S^2\times [0,1)$. I know that $Mod(S^2)$= $\mathbb{Z}/2\mathbb{Z}= Mod(\mathbb{B}^3)$ and $Mod(\mathbb{RP}^2) = 0$ so I'm looking for a way to either extend the isotopy on $\mathbb{RP}^2$ to the whole $\nu(\mathbb{RP}^2)$, or extend the isotopy on the sphere $\partial \nu(\mathbb{RP}^2)$ into the interior. Is that possible?

Is there an easy, topological way to describe $\pi_0(\text{Homeo}(\nu(\mathbb{RP}^2)))$? Alternatively, is there an easy, topological way to show that $Mod(\mathbb{RP}^3)$ is the $2-$cyclic group?