$\newcommand\R{\Bbb R}\newcommand\Si{\Sigma}$The answer to your both questions is yes, regardless of what the covariance matrix $\Sigma$ is.  

Indeed, let $P_X:=X(X^\top X)^{-1}X^\top$, the orthoprojector onto $V_X:=X\R^d$, the column space of the random matrix $X$, so that $P_X\R^n=V_X$. Then for any orthogonal matrix $Q\in\R^{n\times n}$ we have 
$P_{QX}=QX(X^\top X)^{-1}X^\top Q^\top$ and hence
$$V_{QX}=QX(X^\top X)^{-1}X^\top Q^\top\R^n
=QX(X^\top X)^{-1}X^\top\R^n=QV_X.$$
Therefore and because $QX$ equals $X$ in distribution (see the details on this below), it follows that $V_X$ equals $QV_X$ in distribution, for any orthogonal matrix $Q\in\R^{n\times n}$. So, $V_X$ is uniformly distributed. $\quad\Box$

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**Details on why $QX$ equals $X$ in distribution, for any orthogonal matrix $Q\in\R^{n\times n}$:** Write $X=[X_{ij}]_{i\in[n],j\in[d]}$ and $Q=[Q_{ij}]_{i\in[n],j\in[n]}$, where $[n]:=\{1,\dots,n\}$. Then the entries $(QX)_{ij}=\sum_{k\in[n]}Q_{ik}X_{k,j}$ of the matrix $QX$ are zero-mean jointly normal random variables, and for all $i,i'$ in $[n]$ and $j,j'$ in $[d]$ we have
$$E(QX)_{ij}(QX)_{i'j'}
=\sum_{k,k'\in[n]}Q_{ik}Q_{i'k'}EX_{kj}X_{k'j'} \\
=\sum_{k,k'\in[n]}Q_{ik}Q_{i'k'}1(k=k')\Si_{jj'}
=\sum_{k\in[n]}Q_{ik}Q_{i'k}\Si_{jj'}
=1(i=i')\Si_{jj'},$$
so that the covariances of the $(QX)_{ij}$'s do not depend on $Q$.