Let $V$ be a $2n$-dimensional vector space endowed with a nondegenerate skew-symmetric form $q:V \to V^\vee$. We define the isotropic Grassmannian to be $$ X:=G_q(k,V)=\left\{[W] \in \mathbb P \left( \bigwedge^k V\right): W \subset V \text{ and } W \text{ is }q-\text{isotropic}\right\}. $$ We denote the rank $k$ tautological bundle over $X$ by $\mathcal S \hookrightarrow V \otimes \mathcal O_X$. The cokernel will be denoted by $\mathcal Q$. Thanks to the quadratic form, we also have the inclusion $\mathcal S \hookrightarrow \mathcal Q^\vee$ and we denote $\mathcal K$ to be the cokernel $\mathcal Q^\vee/\mathcal S$.
One can prove that the tangent bundle $T_X$ fits in the short exact sequence $$ 0 \to \mathcal S^\vee \otimes \mathcal K \longrightarrow T_X \longrightarrow S^2 \mathcal S^\vee \to 0. $$ Question. Is it true that $T_X$ is the unique non-trivial extension for the short exact sequence? How can we prove it?
I tried to compute $H^1\left(X,S^2\mathcal S \otimes\mathcal S^\vee \otimes \mathcal K\right)$ without significant results.
