The function $x\mapsto (x-K)_+$ is continuous because it is $1$-Lipchitz. Indeed $ |(x-K)_+-(y-K)_+| \le |x-y| $ since $|u_+-v_+|\le |u-v|$ for any $(u,v)\in \mathbb{R}^2$. The solution of you SDE is pathwise continuous since the unique solution is $ S_t = S_0 e^{(\mu-\sigma^2 /2)t + \sigma B_t}$ Then $T \mapsto (S_T-K)_+$ is also pathwise continuous.
To be more precise if $(\Omega,\mathcal{F},\mathcal{P})$ is your probability space then it means that there exists $\Omega' \in \mathcal{F}$ with $P(\Omega')=1$ such that for all $\omega \in \Omega'$, the latter function $T \mapsto (S_T(\omega)-K)_+$ is continuous.