Let $S_n$ be the $n$-th symmetric group. Suppose we have a $n!$-sheeted covering space $$ S_n\to M\to M/S_n $$ where $M$ is a manifold. Let $\mathbb{K}$ be the real numbers $\mathbb{R}$, complex numbers $\mathbb{C}$ or quaternions $\mathbb{H}$. We construct an associated vector bundle $$ \xi:\mathbb{K}^n\to M\times _{S_n} \mathbb{K}^n\to M/S_n $$ where $S_n$ acts on $\mathbb{K}^n$ by permuting the order of coordinates. Then the structure group of $\xi$ is $S_n\subset O(\mathbb{K}^n)$. Let $SO(\mathbb{K}^n)$ denote the sub-Lie group of $O(\mathbb{K}^n)$ consisting of elements with determinant $1$.
Question: can we conclude that:
(1). since the determinant of elements in the structure group can be either $1$ or $-1$, the structure group of $\xi$ cannot be reduced to $SO(\mathbb{K}^n)$?
(2). Moreover, it follows from (1) and by http: //mathoverflow.net/questions/220117 first Chern class of complex vector bundles and first Pontrjagin class of quaternionic vector bundles, $$ w_1(\xi), c_1(\xi),q_1(\xi)\neq 0 $$ for $\mathbb{K}=\mathbb{R},\mathbb{C},\mathbb{H}$ respectively?
(Note: I have a counterexample for the statement (2). But I do not know why it is false.)
